Immune System, Part 2: Crash Course Anatomy & Physiology #46

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What’s true in World of Warcraft is also true in your immune system:

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To defeat your enemy, you have to know your enemy.

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Uncover its weaknesses. Learn how to see it, before it sees you.

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We’ve already talked about how your innate defense system keeps out, or quietly neutralizes,

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pathogens without much too much fuss. But sooner or later, a threat’s gonna come along

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that’s stronger than what the first-responders can handle. That’s when it’s time for

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the adaptive, or acquired immune system to step in.

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While your innate system takes its zero-tolerance policy very seriously, and tries to toast

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any foreign microbe that it encounters, your adaptive system does things differently.

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It has to be expressly introduced to a specific pathogen, and recognize it as a threat, before it will attack.

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As its name suggests, you’re not born with a working adaptive immune system -- it’s

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slow to act, in part because it takes time for it to shake hands with so many pathogens

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and get to know them.

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These introductions may be organic -- like touching a dirty faucet in the bathroom or

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walking into a sneeze cloud.

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Or they may be premeditated, which is why vaccination is pretty much the greatest thing

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to happen to medicine ever.

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But once it’s been introduced to a potential threat, your adaptive defenses never forget

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it. And this ability to remember specific pathogens is one of the key differences between

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the adaptive and innate defenses.

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Another main difference is that adaptive immunity is systemic -- rather than being restricted

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to a particular infection in, say, a sinus or a sliced finger, your adaptive system can

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fight throughout your whole body at once.

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And it does this by deploying one or both of its separate, but cooperating, defenses

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-- your humoral immunity and your cellular defenses.

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Your humoral immunity -- which you might not have heard of before -- works by dispatching

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important proteins that I’m sure you have heard of: antibodies.

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They’re made by special white blood cells, and they patrol the body’s “humors”

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or fluids like blood and lymph, where they combat viruses and bacteria moving around

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the interstitial space between your cells.

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Much of what you know, or have heard about, or think of, when your immune system comes

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up actually has to do with your humoral immunity.

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It’s why, if you had mumps as a kid, you probably don’t have to worry about getting

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it again for the rest of your life.

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It’s also why doctors and nurses and patients who have been infected with the ebola virus

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-- a disease once thought to be incurable -- have lived to tell about it.

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And it’s why vaccinations work.

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Whether you’re protecting yourself from infections or playing an MMO, one of the first

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steps in any good defensive strategy is to be able to tell your friend from your foe.

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And in the case of your immune system, that means being able to identify antigens.

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An antigen could be an invader from the outside world, like a bacterium, virus, or fungus.

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Or it could be a toxin or a diseased cell within your own body.

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But in any case, antigens are large signalling molecules not normally found in the body,

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and they act as flags that get the adaptive immune system riled up.

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So let’s say a flu virus gets inside of you, and it’s floating around trying to

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find a good host cell to start multiplying inside of.

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Before it finds that cell, hopefully it will be paid a visit by one of the stars of your

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humoral response -- a B lymphocyte.

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Like all blood cells, these guys originate in your bone marrow. But unlike other white

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blood cells, they also mature in the bone marrow too.

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And as a B cell matures, it develops the ability to determine friend from foe, developing both

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immunocompetence -- or how to recognize and bind to a particular antigen -- as well as

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self-tolerance, or knowing how to NOT attack your body’s own cells.

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Once it’s fully mature, a B lymphocyte displays at least 10,000 special protein receptors

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on its surface -- these are its membrane-bound antibodies.

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All B lymphocytes have them, but the cool thing is, every individual lymphocyte has

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its own unique antibodies, each of which is ready to identify and bind to a particular kind of antigen.

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That means that, with all of your B lymphocytes together, it’s like having 2 billion keys

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on your immune system’s keychain, each of which can only open one door.

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So, part of your immune system’s strategy is just to win with overwhelming odds: The

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more unique antibodies your lymphocytes have, the more likely it is that one will eventually

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find, bind to, and mark a particular antigen.

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Once they’ve matured, B cells colonize or “seed” your secondary lymphoid organs,

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like your lymph nodes, and start roaming around in your blood and lymph.

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At this point they’re still naive and untested, and they won’t truly be activated until

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they meet their perfect enemy match.

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Which brings us back to the flu virus.

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When the right B cell finally bumps into an antigen it has antibodies for -- usually in

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a lymph node or in the spleen -- and recognizes it, it binds to it. This summons the full

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power of the humoral immune response, and the cell basically goes into berserker mode.

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Once activated, the B cell starts cloning itself like crazy, quickly producing an army

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of similar cells, all with the instructions for the exact same antibodies that are designed

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to fight that one particular antigen.

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Most of these clones become active fighters, or effector cells. But a few become long-lived

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memory cells that preserve the genetic code for that specific, successful antibody.

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This ensures that, if and when the antigen returns, there will be a prepared secondary

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immune response that’s both stronger and faster than the first.

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This is key to why vaccinations are so brilliant and important, which I’ll come back to in a minute.

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But while the memory cells are just there to hang back and record things, the effector,

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or plasma cells, are packed with extra amounts of rough endoplasmic reticulum, which acts

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as an antibody factory.

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These cells can mass-produce the same antibodies over and over for that particular invader,

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spitting them out into the humor at a rate of around 2,000 antibodies per second for

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four or five days until they die.

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And the antibodies they make work the same way that the membrane-bound ones do; they’re just free-floating.

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So they ride the tides of blood and lymph, binding to all the antigens they can find,

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and marking them for death.

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Now, antibodies can’t really do the killing themselves, but they do have a few moves that

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could make it hard for intruders to take hold.

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One of their most effective and common strategies is neutralization, where antibodies physically

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block the binding sites on viruses or bacterial toxins, so they can’t hook up to your tissues.

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And because antibodies have more than one binding site, they can bind to multiple antigens

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at the same time, in a process called agglutination.

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The resulting clumps can’t get around easily, which makes it easier for macrophages

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to come and gobble them up.

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And not only that, but while all this is going on, antibodies are also ringing a chemical

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dinner bell, calling in phagocytes from the innate immune system, and special lymphocytes

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from the adaptive system, to destroy these messy little antigen-antibody clumps.

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So, the point of all this in the short term is to keep you healthy. But in the long term,

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this process also adds to your overall immunity.

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The humoral response allows your body to achieve immunity by encountering pathogens either

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randomly or on purpose.

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Active humoral immunity is what we were just talking about -- it’s when B cells bump

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into antigens and start cranking out antibodies.

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This can occur naturally, like when you catch the flu or get chickenpox or pick up some

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nasty bacterial infection, or it can happen artificially -- particularly through vaccination.

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Most vaccines are made of a dead or extremely weakened pathogen. And they work on the premise

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that, because a secondary immune response is more intense than a primary response, by

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introducing a pathogen into your body, you’re priming it to fight hard and fast should that

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antigen show up again.

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In the case of typically non-fatal infections, like the common flu, this immunity should

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at least spare you from some of the most severe symptoms.

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But in the case of more serious diseases, like polio, smallpox, measles, and whooping

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cough, vaccinations can be truly life-saving.

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Now, some antigens -- like those for mumps or measles -- don’t really change much over

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time, so a few immunizations will leave you set for life.

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But others, like influenza, are constantly evolving and changing their surface antigens.

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So immunity to last year’s flu probably doesn’t work against this year’s flu.

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Still, acquired immunity doesn’t have to be active.

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Babies, for example, naturally obtain passive humoral immunity while still in the womb.

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They receive readymade antibodies from their mothers through the placenta, and later on

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through breast milk.

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And that works pretty well for a few months, but the protection is temporary, because passively

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obtained antibodies don’t live long in their new body. And they can’t produce effector

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cells or memory cells, so a baby’s own system won’t remember an antigen if it gets infected again.

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You can also acquire this kind of temporary passive immunity artificially, by receiving

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exogenous antibodies from the plasma of an immune donor.

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This is what recently saved some doctors and nurses who had contracted the ebola virus

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from infected patients.

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A serum was made from the blood plasma of other medical workers who had been infected,

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and survived.

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The antibodies helped defend the patients from the virus before their own active immunity

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could identify that particular antigen and start creating their own antibodies.

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It’s not the same as a vaccine, which immediately engages your B cells, but it can buy a patient

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some crucial, life-saving time against an infection that would otherwise quickly kill.

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But B cells and antibodies are only part of the immunity equation. There are plenty of

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pathogens that quickly worm their way right inside your cells, where they’re safer from

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the humoral response and free to multiply as much as they’d like.

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Luckily, your immune system has yet another game plan and new set of players ready to

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fight that final battle with cell to cell combat.

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Make sure you catch our final episode next week and learn all about this epic battle royale.

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But as for today, in our second-to-last episode, you learned how the adaptive immune system’s

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humoral response guards your extracellular terrain against pathogens. We looked at how

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B cells mature, identify antigens, and make antibodies, and how antibodies swarm pathogens

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and mark them for death. We also talked about active and passive humoral immunity, and how

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vaccines work.

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Thank you to our Headmaster of Learning, Linnea Boyev, and thank you to all of our Patreon

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patrons. If you are one of those people I just thanked, you make Crash Course possible,

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for the whole world and also for yourself. If you like Crash Course and you want to help

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us make videos like this one, you can go to patreon.com/crashcourse.

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This episode was filmed in the Doctor Cheryl C. Kinney Crash Course Studio, it was written

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by Kathleen Yale. The script was edited by Blake de Pastino. Our consultant is Dr. Brandon

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Jackson. It was directed by Nicholas Jenkins, edited by Nicole Sweeney, our sound designer

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is Michael Aranda, and the Graphics team is Thought Cafe.