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IB DP Biology Study Notes

1.5.3 Lytic Cycle

The lytic cycle is an essential aspect of virology, depicting how numerous viruses reproduce and lead to the eventual destruction of their host cells. It represents a series of sequential events that a virus employs to reproduce within its host cell. By the end of this cycle, the infected cell typically ruptures, releasing new viral particles to further the infection.

Reliance on Host Cells

It's pivotal to understand that viruses are unlike most other organisms. They exist in a realm between the living and non-living, lacking the basic cellular machinery needed to carry out life processes. As obligate intracellular parasites, viruses must invade host cells to:

  • Acquire Energy: Viruses don't possess the metabolic pathways cells do. Hence, they utilise the host cell's energy-generating processes to fuel their activities.
  • Obtain Nutrition: Viruses need raw materials to assemble new viral particles. These building blocks, such as nucleotides for genetic material and amino acids for proteins, are pilfered from the host cell.
  • Protein Synthesis: Viruses are equipped with genetic information to produce proteins, but they lack the machinery to do so. They hijack the host's ribosomes, tRNA, and other translational apparatus to synthesise their proteins.

Detailed Phases of the Lytic Cycle

1. Attachment (Adsorption)

  • The initial step involves the virus recognising and binding to its host cell. This interaction is facilitated by viral surface proteins and specific receptors on the host cell.
  • This specificity ensures that a virus will typically infect only certain types of cells within an organism, termed 'host range'.

2. Entry (Penetration)

  • After attachment, the virus must introduce its genetic material into the host cell.
  • Some viruses enter via endocytosis, where the host cell ingests the virus in a membrane-bound vesicle. Others might fuse directly with the host membrane, releasing their contents inside.
  • Additionally, some viruses need to uncoat themselves, shedding protective layers to release their genetic material.

3. Biosynthesis

  • Inside the cell, the viral genome takes over. Depending on whether it's DNA or RNA, it might integrate into the host's genome or remain independent.
  • The viral genes are transcribed to produce messenger RNA (mRNA), which is then translated by the host's machinery into viral proteins.

4. Maturation (Assembly)

  • Newly made viral proteins and genetic material are then assembled into whole viruses. This assembly line approach is highly efficient, allowing for the rapid production of vast numbers of new virions.
  • Some complex viruses have a specific sequence of assembly, starting with the core genetic material and finishing with external structures like capsids and envelopes.

5. Release

  • The endgame for the lytic cycle is the release of new virions. This usually results in the host cell bursting, a process called lysis.
  • Some viruses have an added layer of complexity, acquiring a lipid bilayer, known as an envelope, from the host cell membrane during this release phase.

Image courtesy of Bruna Espiño dos Santos

A diagram of phases of the Lytic Cycle of viruses.

Lytic Cycle vs. Lysogenic Cycle

It's essential to draw a distinction between the lytic and lysogenic cycles. In the lysogenic cycle, the viral genome integrates into the host DNA and remains passive. Environmental triggers can later activate this integrated DNA, pushing the cell into the lytic cycle.

Implications for Host Cells

A virus adopting the lytic cycle can pose severe challenges:

  • Cell Death: The obvious consequence of the lytic cycle is host cell death due to lysis. This can disrupt tissue integrity and functionality, especially if numerous cells in a particular tissue undergo lysis simultaneously.
  • Immune Activation: Cell death and the release of viral particles can activate the host's immune system. This results in inflammation, fever, and other symptoms typical of a viral infection.
  • Disease Presentation: The physiological changes induced by the lytic cycle and the subsequent immune response contribute to the clinical manifestations of viral diseases.
A diagram showing the difference between the lytic cycle and the lysogenic cycle.

Image courtesy of CNX OpenStax

The Viral Advantage

The lytic cycle, though destructive, offers several advantages to viruses:

  • Rapid Reproduction: The lytic cycle allows for swift production of numerous virions, ensuring the infection spreads quickly.
  • Evasion of Host Defences: By killing the host cell, some viruses can evade immune detection for a while, as they're shielded within the host cell until its destruction.

FAQ

Yes, the lytic cycle can be interrupted at various stages, and this forms the basis for many antiviral treatments. For instance, antiviral drugs can prevent the attachment or entry of the virus into host cells, inhibit the replication of viral genetic material, or block the maturation and release of new virions. One famous example is the class of drugs called protease inhibitors used in HIV treatment. These drugs interfere with an enzyme the virus requires for maturation, thereby preventing the production of infectious viral particles. Identifying and targeting specific stages of the lytic cycle has been a primary strategy in the development of antiviral therapies.

The lytic cycle culminates in the lysis or destruction of the host cell to release new virions, which can cause direct damage to tissues. As numerous cells undergo lysis simultaneously, it can significantly disrupt tissue integrity and function, leading to pronounced symptoms. Moreover, the release of viral particles and cellular debris can activate the immune system, causing inflammation, fever, and other symptoms associated with an immune response. On the other hand, during the lysogenic cycle, the viral genome integrates into the host cell's DNA and remains passive without causing immediate harm. As a result, cells continue to function normally, and there is no direct cellular damage or pronounced immune response, often leading to a lack of noticeable symptoms.

Outside a host cell, viruses exist in a state of dormancy. They are metabolically inactive and do not carry out any biological functions. If a virus doesn't find a suitable host cell, it remains in this dormant state. Over time, environmental factors such as temperature, humidity, and UV radiation can degrade and inactivate the virus, rendering it non-infectious. The duration for which a virus can remain viable outside a host varies widely among different viruses. Some might remain infectious for only a few hours, while others can survive for weeks or even longer in favourable conditions.

Viruses lack the necessary cellular machinery and metabolic pathways to reproduce or synthesise proteins on their own. Unlike living cells, which have ribosomes for protein synthesis, mitochondria for energy production, and other organelles for various metabolic processes, viruses are essentially non-living entities outside a host cell. They're more like complex molecular mechanisms designed to replicate inside a suitable host. Their simplistic structure, often just composed of genetic material enclosed in a protein coat, requires the hijacking of a host cell's machinery to replicate and produce new virions. Thus, without a host, viruses remain inert.

Viruses have a remarkable ability to identify and bind to specific host cells using viral surface proteins that recognise and interact with receptors on potential host cells. This receptor-ligand interaction ensures specificity. The receptors on host cells can be proteins, carbohydrates, or lipids, and the exact nature of these receptors often determines the virus's host range. For example, the HIV virus recognises and binds to the CD4 protein on certain human immune cells. This specificity not only ensures that the virus can enter cells where it can effectively replicate but also restricts the range of cells and species a virus can infect.

Practice Questions

Describe the key steps involved in the lytic cycle of viruses and explain why viruses rely heavily on host cells for their reproduction.

The lytic cycle comprises five main steps: attachment, where the virus binds to a specific receptor on a susceptible host cell; entry, wherein the virus or its genetic material penetrates the cell; biosynthesis, during which the virus's genetic material replicates and viral proteins are synthesised using the host's machinery; maturation, where new viral particles (virions) are assembled; and finally, release, where virions are released from the host cell, often resulting in the cell's lysis. Viruses are obligate intracellular parasites, lacking the cellular machinery to reproduce or carry out metabolic processes autonomously. Therefore, they heavily rely on host cells to obtain energy, nutrition, and to synthesise proteins, effectively hijacking the host's cellular machinery for their proliferation.

Differentiate between the lytic and lysogenic cycles of viruses, highlighting the major difference in the fate of the host cell.

The lytic and lysogenic cycles are two primary mechanisms through which viruses reproduce within host cells. In the lytic cycle, the virus invades the host cell, replicates using the cell's machinery, and then causes the cell to burst or lyse, releasing new virions. This results in the destruction of the host cell. On the other hand, in the lysogenic cycle, the viral genetic material integrates into the host's genome and remains dormant. The host cell is not immediately destroyed. Instead, the integrated viral DNA, called a prophage, can remain inactive for extended periods. Upon certain triggers, the prophage can be activated, leading the cell into the lytic cycle, resulting in the eventual lysis of the host cell.

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