This video, we're going to discuss the normal microbiota as a first line defense mechanism of innate immunity. The normal microbiota is also sometimes referred to as the microbiome. This term refers to the population of resident microbes that grow in and on our bodies, representative of healthy humans. Healthy humans have a healthy microbiome. The normal microbiota or the microbiome is part of the first line of defense in innate immunity and is essential to immune development during and after childbirth. Humans will acquire their microbiota during and after childbirth. Some members of the microbiota protect us by blocking attachment sites that pathogenic microbes use to cause harm. By blocking these attachment sites, they help protect us from these pathogenic microbes. Other members of the microbiota can produce chemicals that are toxic to pathogenic bacteria, once again helping to protect against pathogenic bacteria. Our normal microbiota can protect us from these pathogenic microbes. The normal microbiota can be disrupted; antibiotics can disrupt our normal microbiota, making a person more susceptible to various infections. Because our normal microbiota plays a significant role in protecting us from pathogenic microbes, probiotics, live microbe cultures that are applied or ingested, benefit the normal microbiota. Prebiotics specifically refers to chemicals used to promote the growth of these beneficial consumed microbes. These are consumed along with probiotics. Here, we’re showing a bunch of microbes living on and in our bodies, referred to as our normal microbiome or normal microbiota. In this cartoon, it says, "You are not welcome here," to these pathogenic microbes, and the microbes respond, "Well, you're not really a good host." This cartoon illustrates how the normal microbiome that we have is important for protection and serves as a first line of defense. This here concludes our brief lesson on the normal microbiota as a first line defense mechanism, and we'll be able to get some practice applying these concepts as we move forward in our course. So, I'll see you all in our next video.
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First-Line Defenses: Normal Microbiota: Study with Video Lessons, Practice Problems & Examples
The normal microbiota, or microbiome, serves as a crucial first line of defense in innate immunity, protecting against pathogenic microbes by blocking attachment sites and producing toxic chemicals. Disruption of this microbiota, often due to antibiotics, increases susceptibility to infections. Probiotics, live microbial cultures, and prebiotics, substances that promote beneficial microbes, can help maintain a healthy microbiome. Understanding the role of the microbiome is essential for appreciating its impact on immune development and overall health.
Normal Microbiota
Video transcript
Normal microbiota:
Are the organisms that typically reside on and in your body.
Protect against infection by pathogens.
Enhance infection by pathogens.
Play no role in affecting pathogen growth.
A and B.
C and D.
The human body typically begins to be colonized by its normal microflora:
Before birth, in utero.
When a child first goes to school.
During puberty.
During and immediately after birth.
When an infant gets its first infectious disease.
Do you want more practice?
More setsHere’s what students ask on this topic:
What is the role of normal microbiota in innate immunity?
The normal microbiota, or microbiome, plays a crucial role in innate immunity by serving as a first line of defense against pathogenic microbes. These resident microbes protect us by blocking attachment sites that pathogens use to cause infections. Additionally, some members of the microbiota produce chemicals that are toxic to pathogenic bacteria, further preventing infections. The microbiota is essential for immune development, starting from childbirth and continuing throughout life. Disruption of the microbiota, often due to antibiotics, can increase susceptibility to infections, highlighting its importance in maintaining overall health.
How do antibiotics affect the normal microbiota?
Antibiotics can significantly disrupt the normal microbiota by killing not only the targeted pathogenic bacteria but also beneficial resident microbes. This disruption can lead to an imbalance in the microbial population, making the body more susceptible to infections. The loss of beneficial microbes means fewer defenses against pathogenic bacteria, which can exploit the reduced competition and attachment site availability. Therefore, while antibiotics are essential for treating bacterial infections, their impact on the microbiota underscores the importance of using them judiciously.
What are probiotics and prebiotics, and how do they benefit the microbiota?
Probiotics are live microbial cultures that, when ingested or applied, benefit the normal microbiota by enhancing its population and diversity. They help maintain a healthy balance of beneficial microbes, which is crucial for effective immune defense. Prebiotics, on the other hand, are substances that promote the growth of these beneficial microbes. They serve as food for probiotics, helping them thrive and multiply. Together, probiotics and prebiotics support a robust and healthy microbiome, which is essential for protecting against pathogenic microbes and maintaining overall health.
How does the normal microbiota protect against pathogenic microbes?
The normal microbiota protects against pathogenic microbes through several mechanisms. Firstly, it blocks attachment sites on the body's surfaces that pathogens would use to establish infections. By occupying these sites, the microbiota prevents pathogens from gaining a foothold. Secondly, some members of the microbiota produce chemicals that are toxic to pathogenic bacteria, inhibiting their growth and survival. These combined actions create a hostile environment for pathogens, reducing the likelihood of infections and contributing to the body's innate immune defenses.
Why is the microbiota considered a first line of defense in innate immunity?
The microbiota is considered a first line of defense in innate immunity because it provides immediate and non-specific protection against pathogenic microbes. By occupying attachment sites and producing antimicrobial substances, the microbiota prevents pathogens from establishing infections. This protective barrier is always present and ready to act, unlike adaptive immunity, which requires time to develop a specific response. The microbiota's role in immune development and its ability to quickly respond to microbial threats make it a vital component of the body's innate immune system.