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Immunological Memory

JoVE Core
Anatomy and Physiology
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JoVE Core Anatomy and Physiology
Immunological Memory

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01:23 min

September 12, 2024

Immunological memory, a pivotal pillar of the adaptive immune system, is responsible for the body's ability to remember and respond more swiftly and effectively to previously encountered pathogens. This remarkable feature is what makes vaccines so effective in preventing diseases.

What is Immunological Memory?

Immunological memory is an integral function of the immune system that allows it to recognize and react more rapidly and effectively to pathogens previously encountered. This feature is orchestrated by a complex network of cells, tissues, and molecules forming the adaptive immune system together.

The adaptive immune response is composed of two main cell types: B cells, which produce antibodies that can neutralize pathogens, and T cells, which can either help B cells produce antibodies or kill infected cells directly.

The Role of Antibodies and Lymphocytes in Immunological Memory

Long-lasting antibodies, produced by a type of B cell known as plasma cells, play a crucial role in immunological memory. These antibodies circulate in the blood and other body fluids, providing immediate protection against reinfection by the same pathogen.

Meanwhile, long-living lymphocytes, including memory B cells and memory T cells, may persist in the body after an infection has cleared. These cells are primed to respond more robustly and rapidly upon reencounter with the pathogen, leading to a swifter and more potent immune response.

Primary and Secondary Immune Responses

The primary immune response refers to the immune system's first encounter with a pathogen, during which it produces effector cells to combat the infection and memory cells to remember the pathogen.

In contrast, the secondary immune response occurs when the immune system reencounters the same pathogen. Thanks to immunological memory, this response is typically faster, stronger, and more effective at eliminating the pathogen. Antibody titer, a measure of the amount of antibodies in the blood, typically increases significantly during the secondary immune response.

The Longevity of Immunological Memory

The duration of immunological memory can vary dramatically, depending on factors such as the pathogen, the individual's health status, and the strength of the initial immune response. For some pathogens, like measles or chickenpox, the memory can last a lifetime, providing long-term immunity. For others, like tetanus, the memory may wane over time, necessitating periodic booster shots.

Examples of Immunological Memory in Action

One classic example of immunological memory is infection with chickenpox (varicella-zoster virus, or VZV). After a natural infection with VZV, individual normally will not become reinfected following exposure to the virus in the future.

In the case of viral infections, memory T cells play a crucial role. For instance, in individuals who have recovered from COVID-19, memory T cells can persist for months, ready to mount a rapid response if the virus is encountered again.

Finally, certain fungal infections, like Candida albicans, can induce a strong memory T cell response, enhancing the body's ability to combat future infections.