In this video, watch as Leslie explains how agonists and antagonists affect the receptor sites of the cell.
Enjoy!
Transcript of Today’s Episode
Hello and welcome to another episode of Interactive Biology TV, where we’re making biology fun! My name is Leslie Samuel. In this episode, Episode 18, I’m going to be talking about agonists and antagonists. It almost sounds like a plot for a movie, but it’s not a movie, unless it’s a movie happening inside your body. Anyhow, for today, let’s get into what we’re going to be talking about.
The first thing we’re going to talk about is “What is an agonist?” An agonist is a molecule that mimics the effect of a neurotransmitter, so it does what that neurotransmitter would normally do. An example of that would be succinylcholine mimics the neurotransmitter acetylcholine. So what I’m going to do is I’m going to draw the receptor here, and here we have the cell membrane of the neuron. I’m going to draw it a little different than I’ve been drawing it before. I’m going to have these as the receptor sites. This is where the acetylcholine normally binds to the nicotinic receptor.
I’m going to draw acetylcholine here, but I’m not going to draw it coming here. What I’m going to do is I’m going to draw something that’s slightly different, let’s just say it’s a different color. It’s a similar shape to acetylcholine, and we’re going to call this succinylcholine. When that comes here and it binds to the receptor, same thing here, it comes and it binds to the receptor, the channel opens, which is what it would normally do if acetylcholine binds. And then, sodium ions on the outside end up coming inside the cell. So this would be an example of an agonist. It’s not acetylcholine, it’s something else, and let’s say, in this case, it’s succinylcholine, and that comes, binds to the receptor and causes a similar response. That is an agonist.
Now, let’s look at what an antagonist is. You can probably guess just by reading the word, but an antagonist is a molecule that opposes the effect of a neurotransmitter. So it does the exact opposite. An example of that would be curare, which is an antagonist to acetylcholine that can actually block the binding sites for acetylcholine. So here, we have our nicotinic receptor again, and it’s in the membrane of the cell, and here we have the binding sites.
Out here, we have acetylcholine that wants to bind. However, we have something else that’s around that’s not exactly like acetylcholine and let’s say that its shape looks something like this. That binds to the receptor, and what that does is it blocks the receptor site. So acetylcholine wants to bind and it wants to cause that channel to open, but it’s being blocked so that it cannot bind, and it cannot open the channel for sodium to come in. This would be an example of what curare does. It’s an antagonist, and in fact, curare can cause muscles to become paralyzed because they cannot be activated and sodium cannot rush into the cell, exciting the cell, and exciting the muscle to contract. So that can be a serious thing if you have curare binding to these receptor sites.
That’s really all for this video. I hope you understand the difference between an agonist and an antagonist. If you have any questions or comments about that, go ahead and leave them below. I’ll be happy to answer your question, and maybe even make a follow-up video answering your specific question. That’s it for this video, and I’ll see you on the next one.
are the shapes of the agonists and receptor sites similair?
Hi Tara,
That’s an excellent question. You got it right. It all has to do with having the right shape to fit into the binding site so that it’s able to trigger a response.
@MrSandman0311 You’re welcome ð
Dude you don’t know how grateful i am that you are out there breaking down
this terms and concepts. am currently taking a physiology class and its a
killer to comprehend but your illustration makes it easier to grasp and
understand. THANK YOU
@DatNigerian That’s awesome man. Glad to know it’s helping!
Hey ð not only do your videos help me understand but also REMEMBER this stuff, which is the important part for the exams isnt it!! PLEASE dont stop making these videos.
Hey ð not only do your videos help me understand but also REMEMBER this stuff, which is the important part for the exams isnt it!! PLEASE dont stop making these videos.
@TimmysMummy That’s awesome to hear. Thanks for the feedback. And don’t worry, I’ll be making these videos for a while ð
does he the binding of the antagonists occur at random or in response to some disorder??
You videos are awesome for helping with my cell biology class! My teacher just does not explain this stuff as well as you do! Thanks!
That’s Awesome Jourdyn,
Glad to know you are finding value in the videos. I plan on expanding a lot on what’s here, so make sure to stay tuned ð
All the best!
Suppose your given a graph that indicates the frequency of action potentials firing. There are 4 drugs and two bar graphs for each drug indicating the frequency of stimulation and no stimulation. If a drug shows that there’s an increase of stimulation of Drug A, but also an increase in no stimulation. Should we assume this molecule A is an antagonist? Based on your video, this is what I have analyzed.
Suppose your given a graph that indicates the frequency of action
potentials firing. There are 4 drugs and two bar graphs for each drug
indicating the frequency of stimulation and no stimulation. If a drug shows
that there’s an increase of stimulation of Drug A, but also an increase in
no stimulation. Should we assume this molecule A is an antagonist? Based on
your video, this is what I have analyzed.
@2joann I’m a little confused by what you mean with an increase in stimulation and an increase in no stimulation. Can you clarify?
@2joann I’m a little confused by what you mean with an increase in
stimulation and an increase in no stimulation. Can you clarify?
Is paroxetin an agonist or antagonist?
And what does ketamine do?
Is paroxetin an agonist or antagonist? And what does ketamine do?
Paroxetine is an antagonist to the neurotransmitter serotonin.
Ketamine is an antagonist that acts on the NMDA receptor, which is a receptor for glutamate.
Paroxetine is an antagonist to the neurotransmitter serotonin. Ketamine is
an antagonist that acts on the NMDA receptor, which is a receptor for
glutamate.
ur simply superb in explaining things clearly, i luv the way ur conveying things to us…. thanks a lot dude
ur simply superb in explaining things clearly, i luv the way ur conveying
things to us…. thanks a lot dude
@diphot1 You’re very much welcome. Glad to know you are finding value in the videos!
Brilliant!! Thank you SO much ð
Can anyone help me understand the effects of an agonist at glutamate receptors?
Brilliant!! Thank you SO much ð
Can anyone help me understand the effects of an agonist at glutamate receptors?
Thank you SO SO much!! I seriously cannot tell you how helpful this is to me right now. I’m at my wits end trying to mentally go through the process. I’ll search through the vids to see if you cover everything I’m trying to learn like the specifications on things like the SSRIs etc.
@MultiverseQueen You are very much welcome. Glad to know it’s helping. I have many others. I haven’t covered SSRIs as yet, but that will probably come at some point. All the best!
You are very much welcome. Glad to know it’s helping. I have many others. I haven’t covered SSRIs as yet, but that will probably come at some point. All the best!
Thank you SO SO much!! I seriously cannot tell you how helpful this is to me right now. I’m at my wits end trying to mentally go through the process. I’ll search through the vids to see if you cover everything I’m trying to learn like the specifications on things like the SSRIs etc.
You are very much welcome. Glad to know it’s helping. I have many others. I haven’t covered SSRIs as yet, but that will probably come at some point. All the best!
How can an agonist become an antagonist?
How can an agonist become an antagonist?
How can an agonist become an antagonist?
@ta88iv All questions are answered in the Interactive Biology community forums from now on. Go to the website in the description and then visit the community. This is to make it as efficient as possible as we have multiple people over there to help answer questions.
All the best
All questions are answered in the Interactive Biology community forums from now on. Go to the website in the description and then visit the community. This is to make it as efficient as possible as we have multiple people over there to help answer questions.
All the best
perfect
@ninhbac04 Thanks ð
perfect
Thanks ð
…..does the nervous system ever end? :-/ lol
easy, simple, perfect. great work sir, your effort is greatly appreciated
easy, simple, perfect. great work sir, your effort is greatly appreciated
thank you very much
thank you very much
thank you very much
thank you very much
thank you very much
@1alghanmi You’re very welcome. Stay tuned for more Biology videos coming very soon!
You’re very welcome. Stay tuned for more Biology videos coming very soon!
@swissdedicated Thank you! Please stay tuned for more Biology videos to be uploaded to the website soon!
Thank you! Please stay tuned for more Biology videos to be uploaded to the website soon!
You’re very welcome. Stay tuned for more Biology videos coming very soon!
Thank you! Please stay tuned for more Biology videos to be uploaded to the website soon!
where do agonists and antagonists come from? How are they produced and hw do they get to the synaptic cleft?
where do agonists and antagonists come from? How are they produced and hw do they get to the synaptic cleft?
@msss432 Unfortunately, Leslie won’t be able to answer any specific questions as he is busy creating videos and content for the site. He will get to more Biology topics so, please stay tuned for more!
Unfortunately, Leslie won’t be able to answer any specific questions as he is busy creating videos and content for the site. He will get to more Biology topics so, please stay tuned for more!
Unfortunately, Leslie won’t be able to answer any specific questions as he is busy creating videos and content for the site. He will get to more Biology topics so, please stay tuned for more!
@InteractiveBiology so can someone answer my question?
so can someone answer my question?
so can someone answer my question?
@msss432 Hi! I’m so sorry, but Leslie is busy with a lot of stuff right now. He just doesn’t have the time to be able to go through each mail he gets but, he’s working on more videos and he might just touch more about this topic. So, please stay tuned for more! You can try to go to our Facebook Fan Page community, too. There are some who would answer Biology inquiries from there.
Hi! I’m so sorry, but Leslie is busy with a lot of stuff right now. He just doesn’t have the time to be able to go through each mail he gets but, he’s working on more videos and he might just touch more about this topic. So, please stay tuned for more! You can try to go to our Facebook Fan Page community, too. There are some who would answer Biology inquiries from there.
Hi! I’m so sorry, but Leslie is busy with a lot of stuff right now. He just doesn’t have the time to be able to go through each mail he gets but, he’s working on more videos and he might just touch more about this topic. So, please stay tuned for more! You can try to go to our Facebook Fan Page community, too. There are some who would answer Biology inquiries from there.
@msss432 drugs can be examples of antagonists or agonists.
drugs can be examples of antagonists or agonists.
@xamandaxgatewayx so when you take a certain drug it can either work as an agonists by enhancing the effect of a neurotransmitter, or it can work as an antagonist and prevent the neurotransmitter from working.
so when you take a certain drug it can either work as an agonists by enhancing the effect of a neurotransmitter, or it can work as an antagonist and prevent the neurotransmitter from working.
drugs can be examples of antagonists or agonists.
so when you take a certain drug it can either work as an agonists by enhancing the effect of a neurotransmitter, or it can work as an antagonist and prevent the neurotransmitter from working.
wow…i just got taught by Mike Tyson…i feel privileged..great vid
wow…i just got taught by Mike Tyson…i feel privileged..great vid
@msss432 hi, I only know about curare…I was taught that its an arrow poison…so, imagine one trying to shoot an animal and all of a sudden, ‘mistakenly’ shoots a person around…it will act… (thats the little I know about how it can get there)…
hi, I only know about curare…I was taught that its an arrow poison…so, imagine one trying to shoot an animal and all of a sudden, ‘mistakenly’ shoots a person around…it will act… (thats the little I know about how it can get there)…
hi, I only know about curare…I was taught that its an arrow poison…so, imagine one trying to shoot an animal and all of a sudden, ‘mistakenly’ shoots a person around…it will act… (thats the little I know about how it can get there)…
thank youuu
thank youuu
@msss432
Succinyl-choline (the antagonist) is a medication used in Healthcare, especially in anesthesiology (where people are sedated for surgery). It causes the muscles to relax so it’s easier to work with the body (i.e. intubation, cutting through muscle, opening the cuts)
The antagonist is also a type of medication, lots of examples here. It also causes relaxation, but does so in a different manner (as explained in the video).
Succinyl-choline (the antagonist) is a medication used in Healthcare, especially in anesthesiology (where people are sedated for surgery). It causes the muscles to relax so it’s easier to work with the body (i.e. intubation, cutting through muscle, opening the cuts)
The antagonist is also a type of medication, lots of examples here. It also causes relaxation, but does so in a different manner (as explained in the video).
@Yorreh20 I Meant “Agonist” in the example of succinyl-choline
I Meant “Agonist” in the example of succinyl-choline
Succinyl-choline (the antagonist) is a medication used in Healthcare, especially in anesthesiology (where people are sedated for surgery). It causes the muscles to relax so it’s easier to work with the body (i.e. intubation, cutting through muscle, opening the cuts)
The antagonist is also a type of medication, lots of examples here. It also causes relaxation, but does so in a different manner (as explained in the video).
I Meant “Agonist” in the example of succinyl-choline
Leslie,
Thank you so much for explaining and drawing out the differences between an agonist and an antagonist. You did an awesome job at breaking this concept down and now I can understand it completely! Sincerely,
Michele
Thanks for the feedback Michele!
All the best.
Thank you so much, we are currently studying this in college, and to be honest i was very confused, but you made it very interesting, and i finally understand what is actually going.. Thank you again ð
Thank you so much, we are currently studying this in college, and to be honest i was very confused, but you made it very interesting, and i finally understand what is actually going.. Thank you again ð
What is the difference between agonist and reuptake inhibitor?
@BondComputer007
It’s my understanding is agonist and antagonists (same compounds can be both) depends on the effect they are going to have. A drug that might act as an antagoist for one compound might act as an antagonist. Some can be in the body, or administrated drugs via oral, iv and other routes of administration. I think that’s the best way to exam it. Have a read of some pharmcology text books ð
It’s my understanding is agonist and antagonists (same compounds can be both) depends on the effect they are going to have. A drug that might act as an antagoist for one compound might act as an antagonist. Some can be in the body, or administrated drugs via oral, iv and other routes of administration. I think that’s the best way to exam it. Have a read of some pharmcology text books ð
I would like to know this as well.
I would like to know this as well.
don’t confuse the nervous system with the muscular system hehe (inside joke)
don’t confuse the nervous system with the muscular system hehe (inside joke)
thank you very much I wish the best for this website and for the owner
Thanks! This was very helpful to my Psychology study guide.
i want to know difference between types of antagonist ?
Brilliant again. These videos are really helping me get my head around this subject.
Thanks, you make these hard subjects easy to understand ð
Can you please make a video regarding Chemical Antagonism sir?
simple and easy to understand
thank you
Plain n simple…. Thank you!!!!:)
Very clear, can you please explain the functions of a receptor.
Thank you
Really simply and easy to understand! Thankyou so much, this is helping my Medications class ð
Thank you Leslie, you are the best!!!! Btw, after watching some of your videos onhow action potential works in our brain. And other videos relating to the physiology of the brain I Aced my exam ð
Thank you for all you do. I’m always watching and looking forward for more of your videos
Woohoo, that’s so awesome. Congrats on Acing your exam. You rock!
how does an agonist drug work at synapse? Give an example
Thanks a lot!
thanks! that was so understandable!
thanks. you make it so much easier to understand
thank god for youtube
Black men don’t know pharmacology.
learn to appreciate ,whatever the effort is ………..! No one is an absolute perfect.! right ….!
especially when you are not giving better than him………..! i would appreciate that.!
clear…and very good examples which r easy to undrstand……
Thanks ! ! !
Wow. Fantastic film.
My pal had been obese. He converted his body from 283 lbs of pure fat into 200lbs of purely natural lean muscle. Everyone was shocked. I just signed up personally because I wanna strengthen. He made use of the Muscle Building Bible (Look in Google)…
thank you very much this helped so much
What is an agonist-antagonist ?