- Why carbon is everywhere
- Water - Liquid awesome
- Biological molecules - You are what you eat
- Eukaryopolis - The city of animal cells
- In da club - Membranes & transport
- Plant cells
- ATP & respiration
- DNA, hot pockets, & the longest word ever
- Mitosis: Splitting up is complicated
- Meiosis: Where the sex starts
- Natural Selection
- Speciation: Of ligers & men
- Animal development: We're just tubes
- Evolutionary development: Chicken teeth
- Population genetics: When Darwin met Mendel
- Taxonomy: Life's filing system
- Evolution: It's a Thing
- Comparative anatomy: What makes us animals
- Simple animals: Sponges, jellies, & octopuses
- Complex animals: Annelids & arthropods
- Animal behavior
- The nervous system
- Circulatory & respiratory systems
- The digestive system
- The excretory system: From your heart to the toilet
- The skeletal system: It's ALIVE!
- Big Guns: The Muscular System
- Your immune system: Natural born killer
- Great glands - Your endocrine system
- The reproductive system: How gonads go
- Old & Odd: Archaea, Bacteria & Protists
- The sex lives of nonvascular plants
- Vascular plants = Winning!
- The plants & the bees: Plant reproduction
- Fungi: Death Becomes Them
- Ecology - Rules for living on earth
Hank tells us about the team of deadly ninja assassins that is tasked with protecting our bodies from all the bad guys that want to kill us - also known as our immune system. Created by EcoGeek.
Want to join the conversation?
- 13:00, when a human cell dies, where does it go? does it just keep floating around, or does it somehow get removed from your system?(8 votes)
- Human cells do eat human cells. In fact the process of cell-eating is called phagocytosis, and the eater is known as the phagocyte. Phagocytes are commonly referred to as white blood cells.
Dead cells can come in the form of many things. I classify them into 2 groups, externally and internally.
Firstly, skin shedding is the process in which our dead skin cells get away from our body. They are removed by bathing or scratching. Sometimes, they just drop off or get blown away by the wind. That's why, wherever you go, you are actually leaving bits and pieces of yourself everywhere. The body continuously gets rid of dead cells and scientists estimate that by 7 years, your body would have replaced all old cells into new ones. It can be said that you are a new you. Unfortunately, our brain cells do not die away and get replaced.....pity we don't get smarter.
Internal dead cells refer to the digestive track, in which the cells lining our alimentary canal drop of, and get carried away by the poop. Our poop mainly consists of dead cells that have attached themselves to it, undigested food (fiber) and bacteria. You see, pooping does not relieve you of a tummy ache. It helps cleanse your body.
Next, not all cells which are dead get disposed off. Some living cells, such as red blood cells gets broken down in the spleen. When they are broken down, the materials that made it can still be reused. For example, when RBCs are broken down, hemoglobin is released and further broken down into iron which is stored in the liver. Phagocytes play a part in the breaking down of such substances.(11 votes)
- How do leukocytes 'ask the capillaries' to open a gap between its cell?(6 votes)
- They send a signal using some sort of enzyme or protein to open them up.(5 votes)
- At about7:39you begin talking about the Major Histocompatability Complex which the Natural Killer Cells are looking for to keep our bodies cells safe. Is this related to the blood type issue and why someone with A type blood (like me) can't give to someone with B type blood (like my Best Friend). And if so, what does O type blood not seem to be affected by this?(3 votes)
- MHC has nothing to do with antigens on the cell surface of blood cells.
A blood type has B antigens, therefore, binds to B antibodies in B blood type.
Why is it bad if they bind?
It means erythrocyte agglutination and ultimately death.
That's why A cannot give blood to B nor receive from B but can receive from A, 0 and give to A, and AB.(2 votes)
- Is a nosebleed a common allergic reaction? A nosebleed is my allergic reaction to milk.(2 votes)
- A nosebleed happens when one of the blood vessels in the lining of the nose bursts. Nosebleeds may be caused by infection, injury, allergic reaction, nose picking or an object being pushed into the nostril.
I really didn't know so far of nosebleed as an allergic reaction to milk...
- from8:53, can it be concluded that it is beneficial to allow children to experience bacteria and viruses? would it hinder the child's ability to fight off bacteria and viruses if they were kept in a sterile environment?
yes, vaccinations may work but I assume there would be many more bacteria and viruses in daily life other than the ones from vaccines(3 votes)
- Good thinking.
There are many who agree with you and mice raised "germ-free" are very susceptible to some kinds of infections.
We now also know that having the right microbes in and on our bodies is very important for both physical and mental health!
If you are interested — this article could be a good place to start learning more:
It has also been proposed that too much cleanliness contributes to diseases like asthma that are due to a misdirected immune system.
That idea has several names, but it is best known as the "hygiene hypothesis". See this wikipedia article for details:
- Based off of around4:41, why not we put anti-histamines in food we are allergic of and consume it so we won't get the response and maybe remove the allergy?(3 votes)
- Quite interesting idea, but the answer is no.
First, you need to distinguish food intolerance, food toxicity and food allergy. Three similar terms which fall under the umbrella of hypersensitivity to food.
so food allergy always ends up in activating T cells and involving antibodies. The elicitation phase is mediated either by allergen-specific antibodies (IgE or IgG) or effector T cells, resulting in an inflammatory response of the adaptive immune system.
This is why you mention anti-histamines. But delivering anti-histamines in food is not enough.
So, you can mask anaphylaxis by taking anti-histamines such as adrenaline, but you cannot get rid of allergy.
You can only mask symptoms but never get rid of allergy. If you think f administering targeted drugs, pills with food, they must be hidden in vesicles not to get released until digestion starts, or you could traditionally take antihistamines immediately after eating allergic food and appearance of symptoms.
But why would you do that the only way to avoid allergy is to avoid the food you are allergic to.
Did you know that even antihistamines may be toxic (and especially children may poison themselves if taking carelessly?
- At6:11, if macrophages can kill rogue / cancer cells, why is there still cancer occurring around the world?(2 votes)
- Hank said that macrophages can kill cancer cells (6:08), but also said that natural killer cells are the only ones that can kill other human cells (7:29). What gives?(2 votes)
- Reposting from Kevin D. Fettel:
'Both cell types can kill cancer.
Macrophages primarily do this through phagocytosis, or engulfing the malignant or stressed cell and then destroying it through lysosomal break down.
Natural Killer cells are not able to perform phagocytosis, but rather can secrete cytotoxic chemicals that lead to cellular death. For instance, these chemicals secreted by NK cells punch holes into the membrane (via a protein known as perforin) and also tell the target cell to undergo cell death (via granzyme B).
Both of these cells are part of the innate immune compartment. You may also learn that another type of cell, T cells (specifically cytotoxic CD8+ T cells), may also participate in disease clearance. These T cells are part of the adaptive immune system.'(1 vote)
- Sex and not dying, that's what biology is all about. While the sex part is, I'll grant you, a little bit sexier, not dying is also really fantastic, something that I personally like to do every single day. I personally like to not die in all sorts of ways like I don't jump out of planes, I don't go into active combat zones, I don't do heroin. I can, however, spend time wallowing in the filth with my cute bacon-producing friends here and not have to worry about dying 'cause somehow my body can handle a lot of little devils on my hands, in my air, in my food, little things that literally want to kill me. There are more potential human killers in this pigpen than there are in all of the world's prisons, but I don't have to worry about it because of an elite team of microscopic assassins that live inside my body, my immune system. Ah, that was really close to my hand. (upbeat music) You've heard of some of these little ninjas, others maybe not, but everyone knows the work they do by the trail of dead that they leave behind, pus, being the most disgusting example, and the work that these guys do is pretty hardcore. They not only identify incoming enemies, they eliminate them and then they keep files on them in case their kind ever comes back. So I don't want to freak you out, but you and I are covered in pathogens right now, and you really can't blame them for wanting to get a piece of your action, your warm, high energy, nutrient rich, salty, watery action. Your body's pretty much a theme park for these guys, and although the majority of organisms living inside you actually make your life more comfy, there are some less helpful viruses and organisms from here on out referred to as pathogens that will want to turn your body into a factory for their children. So let's avoid that. We have two basic ways of doing it, innate, or non-specific immunity that responds to all kinds of pathogens the same way and very quickly whether your body as seen that pathogen before or not, and your acquired or adaptive immunity, which develops more slowly and requires your body to learn the wily ways of the pathogen before it defeats it. Every animal has an innate immune system, even sponges, but only vertebrates have the acquired kind. You were born with your innate immune system, and from the second that you wiggled your way out of the sterile environment of your mom and into this germy disgusting world, that system has been protecting you. The thing about the innate immune system is that it doesn't care what it's killing. It doesn't worry about whether it's offing a virus or a bacteria or a fungus, its job is to just keep the enemy from getting in or once it's in to sneak up behind and break its neck ninja style. The first line of defense in keeping sketchy characters out are the skin and the mucous membranes. The skin has so many excellent functions, like keeping your organs in, that it's easy to forget that its primary purpose is to keep things out. It's oily and kind of acidic and really not easy to penetrate, and I'm about to rock your world with this, but your digest tract is also technically the outside of you. Remember how our bodies are basically just built around a tube, right, well the inside of that tube is exposed to as much weird grody stuff as the outside of the tube, so your body treats the digestive tract like the front lines of this war which is one of the reasons why your stomach takes no prisoners with the whole stomach acid situation. In addition to things like skin, we've also got mucous membranes providing another barrier to microbes trying to sneak in. Mucous membranes line all of your internal surfaces that are exposed to the outside like your lungs and the inside of your nose as well as some other parts of your body like the inside of your mouth and your eyelids and your sex organs. Mucous membranes unsurprisingly produce mucous which is a viscous fluid, you've probably heard of it, and it traps microbes and helps sweep them away. This is why illness is so often associated with such awe inspiring amounts of goop. Your second line of defense is your inflammatory response. The honchos here are specialized cells in your connective tissue called mast cells that constantly search for suspicious objects, usually unknown proteins and then release signaling molecules like histamine when they find them. Histamine makes your blood vessels more permeable which allows a whole bunch of fluid to flow to the affected area, and that is what causes inflammation, but it also brings in a crap ton of white blood cells, infection fighters, to go all bowel rog on whatever's trying to make its way in. This is great if you get a splinter in your toe or a bunch of viruses in your face, but sometimes something gets into you that's not actually dangerous, like pollen or dust or a peanut, and your immune system triggers an inflammatory response anyway even though it's not a big deal. This is what we call an allergic reaction, and you know what those are like with the swelling and the redness and the mucous production and the itching and the occasionally a little bit of death, so that is why we take antihistamines to suppress the histamine triggers so our immune system stops freakin' out about nothing. Also, that is why you should always tell people when there are peanuts in your cookies. Most of the immune system activity that happens inside your body's fortress is done by white blood cells or leukocytes. Leukocytes are awesome for a lot of reasons, but one reason is they've got full VIP access to anywhere in the body that they want to go with the exception of the central nervous system, the brain, and the spinal cord which are, for obvious reasons, super high security areas. Leukocytes can move through the circulatory system and when they get to a place where they're needed they can basically send a signal to ask the capillary to open a gap between its cells and then it oozes through that gap at the site of the infection. This is called, get ready for it, diapedesis, from the Greek for oozing through. There are lots of different kinds of leukocytes, like different branches of your own personal microscopic army. The kind specific to the innate immune system are phagocytes, more Greek, this time phago meaning eating, and they're just any cells that ingest microorganisms through the process of phagocytosis. Phagocytes are pretty cool, they can literally chase down invading cells, grab them, and then completely engulf them, and some like the super abundant neutrophils move around the bloodstream and can quickly get to where the action is. Once a neutrophil kills an invading microbe, they basically just roll over and die. Dead neutrophils collect together into what we lovingly call pus. The biggest and baddest of the phagocytes are the macrophages, the big eaters which don't generally travel a lot but instead hang out like body guards in your various organs. Not only do they kill outside invaders, they can also detect when one of your cells has gone rogue like a cancer cell and kill those too, and they, unlike the neutrophils, don't die once they've killed a bacterium, they can eat up to 100 before they die, big eater. Of all the grizzly stuff that goes on in the never ending street war that is your immune system, some of the most gruesome stuff is done by a kind of cell called natural killer cells which reminds me, I think it's time for our very first open letter. (cheerful music) An open letter to 1973. Dear 1973, you had a lot going on, the Vietnam War ending, Roe V. Wade, Watergate, it was a tumultuous time, but part of me wishes that you, 1973, had an opportunity to name everything in biology because you got one chance to name a new type of immune cell, and you named it the natural killer cell, and I freaking love that. Look around at today's script with all of its dendritic cells and macrophages and diapedesises, and I think what if we let 1973 name all these things, would we have spikey death cells and devourerers and oozing action instead? I don't know. Maybe you would have screwed it up, but I don't think we could have done any worse than all this GD Greek we have to deal with all the time. Thanks for the Endangered Species Act, Hank. Okay, natural killer cells, more than just a great name, also the only phagocyte in the innate immune system that destroys other human cells. When your cells are healthy, they have a special protein on their surface called MHC-1, MHC for major histocompatibility complex, but when your cells are infected, say with a virus, or when they're cancerous, they stop producing that protein. So the natural killers are always going around checking up on each of your cells, and when it finds one that's not normal, it pulls out its AK-47 and unloads. Actually, it just binds with it and then secretes an enzyme that dissolves its membrane but still, killing. Finally, dendritic cells are a type of phagocyte that hangs out on the surface of much of your body that comes in contact with the environment in your nose, on your skin, in your stomach and intestines, they eat up pathogens and then carry information about them back to the spleen or the lymph nodes where it passes intelligence about what's going on in the war front to the acquired immune system. I actually studied dendritic cells in my undergraduate thesis, and I kind of fell in love with them. They're lethal but they're also intelligent. Great heroes for any Robert Lublin novel. To be fair though, macrophages can do this too. The activity of these cells give us a chance to transfer from the innate immune system to the acquired immune system which is going to make things a little more complicated. The acquired system has to learn as much as it can about every pathogen it interacts with, store that information, and then use it to invent defense against them. It's your super elite double secret strike force delta. You get to work building your acquired immune system immediately after you're born harvesting bacteria and other stuff, not just good bacteria that can help your guts out but also harmful ones that your body learns from and stores information about. That system keeps an eye out for any foreign substance, a toxin, a virus, a bacteria, even parts of those things that could be telltale signs of a bad guy. We call those signs antigens, a word that comes from antibody generator. An antigen is anything that causes your immune system to ID a pathogen and then create an antibody against it. Antibodies aren't cells, they're highly specialized proteins produced by B cells to recognize and help lay the smack down on intruders, but antibodies can't kill invaders themselves. They're just little proteins after all. The best that they can do by themselves is sort of just swarm all over the invader making it harder for it to move and to excrete toxins or otherwise infiltrate healthy cells, but more often antibodies serve as tags attaching themselves to the scumbags and then releasing chemical signals to nearby phagocytes alerting them that it's dinnertime. You're acquired immune system also has its own type of white blood cells, not phagocytes, which go after everything that looks a little bit sketchy, but lymphocytes which go after specific things that they already know about it. There are two major types of lymphocytes, the T cells which form in your bone marrow and then migrate and mature in the thymus gland right behind your breast bone, and the B cells which originate and mature in the bone marrow. What T and B actually stand for is a long story, but if it helps you to remember, Ts mature in the thymus, Bs in the bone marrow. We have two different types of lymphocytes because our bodies have two different types of acquired immunity, the cell-mediated response, which is for when the cells are already infected and the humoral response for when the infection is just in the humors, the body's fluid, not in the cells. First let's look at the cell-mediated response. This process mainly involves T cells and there are quite a number of different types of them. Helper T cells have a cute sounding name but in a lot of ways, they call the shots for the whole immune system. While they can't kill pathogens themselves, they activate and direct the cells that can. If 1973 had named them, they might have been called admiral T cells or something more awesome. Helper T cells get their information from other immune cells that are out crackin' skulls, say for instance, a macrophage finds a pathogen and destroys it. After the deed has been done, it has the ability to shred up the proteins from an invader and put a bit of that antigen on its membrane surface. This is called antigen-presentation because the cell is presenting antigens. A helper T cell can detect when this happens, and it comes over to attach itself to the presented antigen. The two cells talk to each other chemically. The antigen presenting cell produces a chemical called interleukin 1 which basically tells the helper T cell boss, I found this guy over here and then I broke his neck and then he stuck his guts all over my cell wall. The helper T cell gives it a look and then releases a chemical called interleukin 2 which is like a bull horn, an alarm that tells all the lymphocytes in the are there are problems here, we've got a problem over here, it's sector 50. This alarm activates a couple different things all at once. First, the helper T cell starts making copies, tons of copies of itself. Most of those copies differentiate into effector T cells which travel around secreting signaling proteins that stimulate other nearby lymphocytes to take action. Most of the rest of them become memory T cells. They're the ones that keep a record of the intruder and provide us with future immunity against it. And now for the saddest story of the day. What happens when a cell gets infected, so infected that it knows that it's a goner, that it in fact is being converted from a healthy useful part of the body to an evil zombie farm pumping out viruses or bacteria suddenly co-opted to help destroy everything it loves? Well, with its last bit of strength, it'll start presenting antigens, not asking to be rescued but instead asking for a mercy killing. A cytotoxic T cell has the job of granting that request. Once a cytotoxic T cell gets the message from the helper T cells that there is an infection to deal with, it starts patrolling the area for any normal cells presenting antigens. When it finds one, it latches onto it and releases enzymes that create holes in the cell's membrane and eventually breaks down the whole cell killing the cell and the pathogen in the process. A human cell killing another human cell. And now, for the humoral response. The humoral response is designed to catch pathogens that are floating around in your body that haven't actually invaded any of your cells yet. The primary players are B cells which are constantly patrolling your blood stream like cops walkin' the beat until they get a signal from a helper T cell that something's wrong. B cells are covered in antibodies that can detect and bind to a specific antigen. A single B cell can be covered in a forest of up to 100 thousand antibodies, say for the virus that causes the common cold, and the B cell next to it will have just as many receptors for a different antigen, for chicken pox or something. When a B cell bumps into a pathogen that it recognizes, it attaches to it and starts cloning itself like crazy. Suddenly there are tons of that B cell with the same receptor, but during the cloning process, the clones differentiate into new versions of the original just like the T cells did. Most turn into plasma or effector cells which use the antibody as a blueprint to create a crap ton of antibodies for that specific pathogen, 200 antibodies per second. Once these antibodies are released, they bind to the pathogens like crazy marking them for death until the phagocyte can come along and the dirty work. The rest of the cloned B cells mostly become memory cells which have the same receptor and stick around providing future immunity from this invader. And we are now very out of time but I really love this stuff so I didn't want to gloss over anything. Mucous, natural killer cells, macrophages, killing things, breaking them up and sticking them on their cell membranes, effector cells spewing out antibodies and memory cells making sure that our immune systems hold that grudge all because my absolute favorite thing to do every single day is not die.