Introduction to B Lymphocytes - Online Tutor, Practice Problems & Exam Prep

In this video, we're going to begin our introduction to B lymphocytes or B cells. And so first, we need to recall from some of our previous lesson videos that B lymphocytes or B cells play an important role in adaptive humoral immunity. Recall that humoral immunity is the part of the adaptive immune system that is going to be targeting and destroying extracellular pathogens or pathogens that are on the outside of host cells. This humoral immunity will be able to destroy these extracellular pathogens by using B cells, as well as using what are known as antibodies. We'll get to talk a lot more about antibodies as we move forward in our course.

Now also recall from some of our previous lesson videos that dendritic cells, which are antigen-presenting cells or an APC, have both MHC class 1 and MHC class 2 molecules. That means that they're capable of activating T cells, both types of T cells, the cytotoxic and the helper T cell. When they activate the helper T cell, the helper T cell will then go on to be able to activate the B cell, and then the B cell will be able to carry out its immune functions.

If we take a look at our image down below, you'll notice it's an image that we've seen before in our previous lesson videos. Once again, we have our primary lymphoid organs at the top which include the thymus and the bone marrow. The thymus is where the T cells fully develop and the bone marrow is where the B cells fully develop. Notice that because we've briefly discussed the T cells already, the T cell area over here is pretty much all grayed out because we've already talked about it briefly in our previous lesson videos. In this video, we're going to be focusing on the B cells.

These fully matured naive B cells will migrate from the primary lymphoid organs to the secondary lymphoid organs, and so here we have a naive or inactive B cell. This naive B cell has not yet encountered an antigen, but when it does encounter its antigen, it will be able to internalize that antigen, process that antigen, and then display that antigen on its MHC class 2 molecules. When it's displaying those MHC class 2 molecules, those antigens on those MHC class 2 molecules, the effector helper T cell can recognize those antigens on the MHC class 2. The effector helper T cell can then release cytokines that can ultimately activate the B cell. The activated B cell, as we've discussed before in some of our previous lesson videos, is going to be able to proliferate or divide to create clones as well as differentiate into either memory B cells as you see here, and the memory B cells will be important for a secondary infection, or the activated B cells could differentiate into what are known as plasma cells, and plasma cells are really the effector B cell.

These plasma cells are going to be able to release and secrete antibodies, and these antibodies can carry out many different types of immune functions. As we move forward in our course, we're going to talk a lot more details about this activation process of the B cells, the differentiation of the memory and the plasma cells, and then also the antibodies that these plasma cells can produce. This here concludes our brief introduction to these B lymphocytes or B cells, and again, we'll be able to learn more as we move forward. So, I'll see you all in our next video.

In this video, we're going to briefly discuss B cell receptors. First, we need to recall from some of our previous lesson videos that B cells develop in the bone marrow. These B cells have thousands of identical B cell receptors embedded in their membranes. These B cells are also associated with what are known as antibodies. That's because these B cells have the ability to differentiate into what are known as plasma cells that secrete many antibodies. We'll get to talk a lot more about plasma cells and antibodies as we move forward in our course. But going back to these B cell receptors, these B cell receptors are commonly abbreviated as BCRs. Again, each B cell is going to have thousands of identical BCRs embedded in their membrane.

Now, these B cell receptors or BCRs, are receptors that allow B cells to recognize and attack extracellular pathogens. One of the main differences between B cell receptors, or BCRs, and T cell receptors, or TCRs, is that, recall, TCRs do not bind to free antigens. TCRs can only bind to presented antigens on MHCs. However, B cell receptors can actually bind to free-floating antigens. The free-floating antigens are able to bind to the BCRs. When these free-floating antigens bind to the BCRs, they can then be internalized and processed, and then those free-floating antigens can be presented by the cell for activation by helper T cells, presenting those free-floating antigens on their MHC class 2 molecules.

Some important things to note about these BCRs is that BCRs are practically membrane-embedded antibodies. The structures of antibodies are going to resemble the structure of BCRs and vice versa, and they have very similar overall structures. We'll get to talk about the structure of BCRs and antibodies in more detail as we move forward in our course.

Notice on the left-hand side over here, we're showing you a B cell. This B cell can have, again, thousands of identical BCRs embedded in their membrane, these are the B cell receptors. Notice that these BCRs take on a shape that resembles that of the antibodies they eventually produce. The BCRs are capable of binding to free antigens, antigens that are not being presented. If we zoom into this BCR over here, what you’ll notice is that the BCR has a Y-shaped structure you see right here. This is our B cell receptor, and this yellow region represents the antigen-binding site of the B cell receptor. This is the region of the BCR that binds the antigen. Notice that there are two antigen-binding sites allowing for the BCR to bind to two antigens at once. We're showing you a free antigen and notice that it's binding to this specific epitope of the free antigen.

This concludes our brief introduction to B cell receptors (BCRs) and their ability to bind to free antigens. We’ll be able to get some practice applying these concepts and learn more as we move forward in our course. I’ll see you all in our next video.

In this video, we're going to continue our introduction to B lymphocytes by talking about the ability for naive B cells to become effector plasma cells and memory B cells. First, we need to know that before a B cell encounters a free antigen, that B cell exists in an inactive form that we refer to as a naive B cell. Once again, a naive B cell is really just an inactive B cell that has not yet encountered its free antigen. Upon encountering its free antigen and then presenting that free antigen on an MHC class 2 molecule, the naive B cells are going to be bound and activated by helper T cells. Recall from our previous lesson videos that helper T cells can help to activate B cells. These activated B cells are capable of proliferating or multiplying to create identical clones of itself, as well as differentiating or changing its phenotype to become either an effector plasma cell or a memory B cell.

The effector plasma B cells are going to be short-lived cells that make antibodies. They can make thousands of antibodies per second. So, they're making lots and lots of antibodies. These antibodies, as we'll learn moving forward in our course, are capable of immediately responding to the first infection. They are able to respond to the infection in many different ways. The memory B cells, on the other hand, are long-lived cells and do not respond immediately to the first infection. Instead, these memory B cells, that are long-lived cells, somewhat remember the antigen and their future infection, and help eliminate that future infection even faster than the primary infection was eliminated.

If we take a look at our image down below, we can get a better understanding of the ability for the naive B cell to differentiate into either an effector plasma cell or a memory B cell. Notice over here on the left-hand side what we have is a naive B cell, an inactive B cell. When this naive B cell encounters a free antigen, as you see right here, a free-floating antigen that's not being presented, this free antigen can be internalized into the B cell, processed, and then presented on MHC class 2 molecules. The MHC class 2 molecules are going to allow helper T cells to activate the naive B cell. Activation of the naive B cell will allow the B cell to differentiate either into a memory B cell as we see right here, or it would allow the B cell to differentiate into a plasma cell. The plasma cell would be the effector cell, again capable of releasing and producing thousands of antibodies per second, releasing those antibodies into the environment, and those antibodies that are released into the environment can then carry out several different immune responses, which we'll get to talk about as we move forward in our course.

Recall that on these B cells, they have B cell receptors or BCRs. The BCRs that a B cell has are pretty much membrane-embedded versions of the antibodies that that B cell ends up producing after it differentiates into a plasma cell. This concludes our brief lesson on how naive B cells can become effector plasma cells and memory cells. We'll be able to get some practice applying these concepts and learn more as we move forward in our course. So, I'll see you all in our next video.