164 Chapter 9
This antibody can bind
to a type of virus
This antibody can bind
to a species of bacteria
immunoglobulin Ig; an
antibody.
antibodies: Defense against threats outside Cells
Because of the great diversity of antigen receptors,
there’s a good chance the lymph node also contains an
inactive B cell with receptors for the invader’s antigen. If
so, the B cell binds to the bacterial antigen and displays it
(again, in an antigen–MHC complex) at the B cell’s surface
(Figure 9.12B). This processing activates the B cell. It also
allows helper T cells in the node to recognize and bind to
the antigen–MHC complex. Now the T cell and active B cell
can interact. The T cell begins to release cytokines that spur
the B cell to divide. Its descendants become plasma cells or
memory B cells.
The plasma cells release huge numbers of antibodies
into the bloodstream—up to 2,000 each minute. When
any of these antibodies binds to an antigen, it marks the
invader for destruction by phagocytes and complement
proteins. The memory B cells will be available to respond
quickly to the antigen if it attacks the body another time.
n Antibodies flag invaders or toxins so that the pathogens
can be destroyed or eliminated.
antibody-mediated immune responses
produce a flood of antibodies
Antibodies don’t kill pathogens or directly destroy toxins
in body fluids. Instead, antibodies mark these invaders
so that other mechanisms prevent them from harming
body cells.
When a B cell forms, the genetic mechanisms involved
ensure that it has receptors for only one antigen—such as a
particular bacterial or viral protein. If a B cell is activated,
the antibodies that the resulting plasma cells make will
target the same antigen. Figure 9.11 shows the typical Y
shape of simple antibodies that bind bacteria or viruses.
The place where an antibody can bind an antigen usually
is near the tip of the two “arms.” As antibodies form, they
are embedded in a B cell’s plasma membrane so that the
two arms stick out.
Antibody-mediated immune responses get under way
in the lymphatic system, especially in lymph nodes and the
spleen. Dendritic cells, T cells, and B cells all participate.
Figure 9.12 takes you through the
basic steps of the response, starting
with the point when a dendritic cell
responds to the invasion.
Remember from Section 9.5 that dendritic cells serve
as antigen “presenters.” A dendritic cell that detects the
invader engulfs it, processes the antigen it bears, and then
displays it in an antigen–MHC complex (Figure 9.12A).
When receptors of a responding helper T cell bind to the
complex, the two cells trade signals. The T cell begins to
divide, giving rise to effector and memory helper T cells
that have the same antigen receptors. (When you have an
infection, the accumulation of these T cells is what makes
your lymph nodes swell.)
Figure 9.12 Animated! A An antibody-mediated immune
response occurs when B cells make antibodies to an antigen.
In this example, the invader is a bacterium. (© Cengage Learning)
Figure 9.11 Antibodies can bind to antigens. Each kind of
antibody can bind only one kind of antigen. The antigen fits
into grooves and bumps on the antibody molecules. (From Frances
Sienkiewicz Sizer; Eleanor Noss Whitney, Nutrition: Concepts and Controversies,
© 2002 Cengage Learning)
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Other
cytokines
Antigen–MHC complex
Helper T cells
A
Signals from
cytokines
Bacterial cell with
antigens on its surface
Dendritic cell
that engulfs the
invader and
processes it
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