Acellular Infectious Agents: Viruses, Viroids & Prions - Online Tutor, Practice Problems & Exam Prep

In this video, we're going to begin our lesson on acellular infectious agents, including viruses, viroids, and prions. Now recall from our previous lesson videos that the term acellular or non cellular is just a term that means not consisting of or containing cells or cellular structures. And so anything that is acellular is not going to be made of cells, and that includes these acellular infectious agents, viruses, viroids, and prions. Now by definition, anything that is acellular and is not made of cells is also not going to be considered living. Because recall that the smallest and most fundamental unit of life is the cell. And so if it's not consisting of cells, it's not technically by definition considered alive. And so all of these acellular infectious agents are not technically considered alive because they lack many of the features of life, including not being cellular. And so these acellular infectious agents, once again, are noncellular or acellular, not composed of cells. And so they're noncellular objects that will contaminate and affect living cells. And once again, this includes viruses, viroids, and prions are the three groups of acellular infectious agents. And so if we take a look at our image down below at our map of the microbial world, recall that in our previous lesson videos, we already introduced the cellular organisms, including the prokaryotes such as bacteria and archaea, as well as the microscopic eukaryotes, including fungi, the protists, algae, and protozoa, as well as helminths. And so this green region that I've highlighted here on the map represents the living aspect of the microbial world, the living cellular components, the living cellular organisms. But then notice over here on the right-hand side is where the acellular infectious agents fall that are not composed of cells and are not technically considered alive. And this once again includes the viruses, viroids, and prions. And as we move forward in our course, we're going to talk more about each of these groups. But for now, this here concludes our brief introduction to acellular infectious agents, and we'll be able to talk more about them as we move forward. So I'll see you all in our next video.

In this video, we're going to begin our introduction to viruses. But later in our course, in a different video, we are going to talk a lot more about the details regarding the structure and function of viruses. This video here is just an introduction. A virus can be defined as an obligate intracellular parasite that is made of DNA or RNA, but not both. This DNA or RNA will be packed into a protein coat, and sometimes the DNA and RNA can be packed into a lipid envelope. Now, we have said that a virus is an obligate intracellular parasite, and to define an obligate intracellular parasite, we can define it as substances that can only replicate inside a host that they infect or harm. Thus, this virus can only replicate and reproduce when it is inside the host that it infects and harms. All forms of life can actually be affected or infected by different types of viruses, including bacteria, archaea, and eukarya. All forms of life can be infected by different types of viruses. Frequently, viruses will kill the cells that they infect. However, they can also silently remain inside of the host without killing them. This is an idea that we'll get to talk more about later in our course. But if we take a look at our image below at our introduction of viruses, notice on the left-hand side, we are showing you one type of virus known as a bacteriophage, which is a type of virus that infects bacteria. Notice that it has a protein coat on the perimeter in pink color, and then on the inside, there is genetic material either DNA or RNA. This is a micrograph of an Escharichia virus T4 bacteriophage. Then, on the right-hand side, what we are showing you is a human virus, which takes on a different structure. However, it still has a protein coat and still is going to have genetic material. And of course, we're all familiar with the SARS CoV-2 virus that caused COVID-19, the COVID-19 pandemic. Here is a visual depiction of the SARS CoV-2 virus that caused COVID-19 disease in humans. This here concludes our brief introduction to viruses, these obligate intracellular parasites. But once again, later in our course, we're going to talk a lot more about the details concerning the structure and function of viruses. For now, I'll see you all in our next video.

This video, we're going to begin our introduction to viroids. Now, viroids, like viruses, are also obligate intracellular parasites that must infect a living cell and be inside of the cell to replicate. Unlike viruses that are made up of DNA or RNA as well as protein and sometimes lipids, viroids are only made of a single short strand of RNA that forms a closed ring. Viroids are only known to infect plants and cause plant diseases. They are not known to infect other groups of life other than plants, and there's not much known about how viroids originated or how they can cause disease in plants. Therefore, they are under investigation, and there is a lot of research to find out more about these viroids.

Now, if we take a look at our image down below of the viroids, what you'll notice is we're showing you this red structure here which is representing the circular single-stranded RNA, which we call the viroid. Notice that it is able to base pair with itself, but it is going to complete a circle here, a closed ring. It can infect plants and cause plants to wilt and ultimately die.

Down below what you see right here is another example of a viroid, specifically potato spindle tuber viroid or PSTV, which is a viroid that infects potatoes. It can infect normal potatoes and cause the potatoes to become PSTV potatoes or potatoes that have been infected by the potato spindle tuber viroid. This here concludes our brief introduction to viroids, these single short strands of RNA that form a closed ring and are obligate intracellular parasites. Once again, we'll be able to talk more about viroids later in our course. This is just the introduction. So, I'll see you all in our next video.

In this video, we're going to introduce prions. And so the term prions is actually derived from proteinaceous infectious agents. And you can see that with the bolded terms here to help create that word, prions. And so by proteinaceous, what this is referring to is that these infectious agents are made of proteins and only proteins. And these prions, like viruses and viroids, are obligate intracellular parasites, which once again just means that they must infect a living cell and get inside of the cell in order to replicate themselves. And so, unlike viruses and viroids, these prions, once again, are made of only misfolded proteins. So they only consist of proteins and that's why they are proteinaceous. And, you can see that with the prions here. Now prions, again, they are misfolded proteins themselves. However, these misfolded prion proteins can cause normal proteins to misfold. And ultimately, a misfolded protein is going to lose its function, and that can cause disease. And so prions are linked to several slow degenerative diseases such as scrapie and mad cow disease.

And so if we take a look at our image down below over here on the left-hand side, notice that we're showing you the structure of a normal protein. And over here on the right, what we're showing you is the structure of the prion, which is going to be a misfolded protein itself. And so notice that the shape of this prion is different than the shape of the normal protein. And so over here on the right-hand side, we're showing you the brain of a healthy individual that's going to have normal proteins. However, if this individual is infected with a prion, then the prion can cause normal proteins to transform into prions. And so you can see that those normal proteins have transformed into prions, misfolded proteins that have lost their function, and that can lead to diseases. And so this represents the diseased brain.

And so this here concludes our brief introduction to prions, and once again, we'll be able to talk more about prions later in our course. But for now, I'll see you all in our next video.