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Lytic Cycle of Bacteriophages01:30

Lytic Cycle of Bacteriophages

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Bacteriophages, also known as phages, are specialized viruses that infect bacteria. A key characteristic of phages is their distinctive “head-tail” morphology. A phage begins the infection process (i.e., lytic cycle) by attaching to the outside of a bacterial cell. Attachment is accomplished via proteins in the phage tail that bind to specific receptor proteins on the outer surface of the bacterium. The tail injects the phage’s DNA genome into the bacterial cytoplasm. In the...
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DNA Bacteriophages01:26

DNA Bacteriophages

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Bacteriophages, or phages, are viruses that specifically infect bacteria, utilizing their genetic material to hijack host cellular machinery for replication. DNA bacteriophages employ single-stranded DNA (ssDNA) or double-stranded DNA (dsDNA) genomes. These phages exhibit diverse replication strategies and host interactions, influencing their ecological roles and applications in biotechnology and medicine.ssDNA BacteriophagesssDNA phages, with their small genomes, utilize unique strategies to...
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Lysogenic Cycle of Bacteriophages00:43

Lysogenic Cycle of Bacteriophages

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In contrast to the lytic cycle, phages infecting bacteria via the lysogenic cycle do not immediately kill their host cell. Instead, they combine their genome with the host genome, allowing the bacteria to replicate the phage DNA along with the bacterial genome. The incorporated copy of the phage genome is called the prophage. Some prophages can re-activate and enter the lytic cycle. This often occurs in response to a perturbation, such as DNA damage, but can also transpire in the absence of...
63.8K
Viral Replication: Lytic Cycle01:20

Viral Replication: Lytic Cycle

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Bacteriophages, or phages, are viruses that specifically infect bacteria. Among them, T-even bacteriophages, such as T4, exhibit a well-characterized lytic replication cycle in Escherichia coli (E. coli). This process ensures the rapid proliferation of the virus while ultimately leading to the destruction of the bacterial host.Attachment and DNA InjectionThe infection process begins with the recognition and binding of the T4 phage to the E. coli cell surface. Tail fibers of the phage...
360
Delivery Pathways to the Lysosome01:36

Delivery Pathways to the Lysosome

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Eukaryotic cells use different mechanisms to eliminate toxic waste obsolete and worn-out substances. Lysosomes play a pivotal role in this, and hence, these substances are carried to the lysosome from other parts of the cell and extracellular space through different pathways. The most elaborately studied pathways to the lysosome are the endocytic pathways.
Endocytosis
In endocytosis, the cell membrane takes up macromolecules and particles from the surrounding medium. Clathrin-mediated...
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Intracellular Movement of Viruses and Bacteria01:10

Intracellular Movement of Viruses and Bacteria

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Intracellular bacteria and viruses often comprise a group of highly infectious pathogens that can cause several diseases. Bacterial pathogens include those belonging to the genus Rickettsia responsible for conditions such as rocky mountain spotted fever and the Mediterranean spotted fever; Chlamydia, a genus responsible for a sexually transmitted disease; Coxiella burnetii, an agent responsible for Q fever. Viral pathogens include vaccinia—a poxvirus, and herpes simplex virus—a...
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Related Experiment Video

Updated: Oct 3, 2025

Synthesis of Infectious Bacteriophages in an E. coli-based Cell-free Expression System
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Synthesis of Infectious Bacteriophages in an E. coli-based Cell-free Expression System

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The Pathways to Create Containers for Bacteriophage Delivery.

Egor V Musin1, Aleksandr L Kim1, Alexey V Dubrovskii1

  • 1Institute of Theoretical and Experimental Biophysics, Russian Academy of Science, Institutskaya St., 3, 142290 Puschino, Moscow Region, Russia.

Polymers
|February 15, 2022
PubMed
Summary

Bacteriophage instability hinders phage therapy. Encapsulating bacteriophages in CaCO3 microparticles, not polyelectrolyte microcapsules, preserves their activity for delivery, offering a solution to antimicrobial resistance.

Keywords:
CaCO3E. colibacteriophagedextran sulfateencapsulationmicrocapsulespolyarginine

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Area of Science:

  • Microbiology
  • Biotechnology
  • Materials Science

Background:

  • Antimicrobial resistance is a significant global health challenge.
  • Bacteriophage therapy shows promise but is limited by phage instability.
  • Developing stable bacteriophage delivery systems is crucial for therapeutic advancement.

Purpose of the Study:

  • To explore methods for creating encapsulated bacteriophages for enhanced delivery.
  • To evaluate the stability of bacteriophages within different microcapsule systems.
  • To identify a suitable delivery vehicle for bacteriophages to overcome barriers like the stomach.

Main Methods:

  • Investigated the effect of proteolytic enzymes on polyelectrolyte microcapsules (dextran sulfate/polyarginine)3.
  • Assessed bacteriophage activity after encapsulation in polyelectrolyte microcapsules and CaCO3 microparticles.
  • Tested bacteriophage survival in a high pH medium (pH 9.02).

Main Results:

  • Protease from Streptomyces griseus degraded polyelectrolyte microcapsule shells.
  • Bacteriophages lost activity within polyelectrolyte microcapsules after 16 hours.
  • Bacteriophages encapsulated in CaCO3 microparticles retained activity before and after particle dissolution.
  • High pH did not affect bacteriophage or E. coli survival.

Conclusions:

  • Polyelectrolyte microcapsules are unsuitable for bacteriophage delivery due to inactivation.
  • CaCO3 microparticles are a promising container for bacteriophage delivery.
  • CaCO3 microparticles can protect bacteriophages during passage through the acidic stomach barrier.