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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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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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Lysogenic Cycle of Bacteriophages00:43

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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...
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Viral Replication: Lysogenic Cycle01:16

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The lysogenic cycle is a crucial viral replication strategy that allows bacteriophages to persist within host cells without immediately destroying them. This process is primarily observed in temperate phages, such as bacteriophage lambda (λ), which infects Escherichia coli. The cycle allows the viral genome to persist across bacterial generations while keeping host cells viable.Integration of the Viral GenomeUpon infection, bacteriophage lambda attaches to the bacterial surface and injects...
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Viral Replication: Lytic Cycle01:20

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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...
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Updated: Sep 15, 2025

A Virtual Machine Platform for Non-Computer Professionals for Using Deep Learning to Classify Biological Sequences of Metagenomic Data
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Deep Learning Transforms Phage-Host Interaction Discovery from Metagenomic Data.

Yiyan Yang1, Tong Wang1, Dan Huang1

  • 1Channing Division of Network Medicine, Department of Medicine, Brigham and Women's Hospital, Harvard Medical School, Boston, MA 02115, USA.

Biorxiv : the Preprint Server for Biology
|July 16, 2025
PubMed
Summary
This summary is machine-generated.

We developed PHILM, a deep learning tool to predict phage-host interactions (PHIs) from metagenomic data. PHILM significantly improves PHI prediction accuracy and offers novel insights into microbiome dynamics and disease classification.

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Area of Science:

  • Microbiome research
  • Computational biology
  • Virology

Background:

  • Microbial communities are vital for ecosystem functions, with phages playing a key role in shaping them.
  • Existing methods for inferring phage-host interactions (PHIs) from metagenomic data suffer from low sensitivity and limited ecological accuracy.

Purpose of the Study:

  • To introduce PHILM, a novel deep learning framework for predicting PHIs directly from metagenomic taxonomic profiles.
  • To overcome the limitations of current computational approaches for PHI inference.

Main Methods:

  • Developed PHILM, a deep learning framework utilizing metagenomic taxonomic profiles.
  • Validated PHILM using synthetic datasets from ecological models and real-world metagenomic data.
  • Compared PHILM against co-abundance-based and assembly-based methods for PHI inference.

Main Results:

  • PHILM consistently outperformed co-abundance-based methods in inferring PHIs.
  • Applied to a large dataset, PHILM identified 90% more genus-level PHIs than assembly-based approaches.
  • PHILM's latent representations effectively captured microbial succession and improved disease classification accuracy.

Conclusions:

  • PHILM provides a powerful new computational framework for predicting phage-host interactions from metagenomic data.
  • The framework offers significant advancements for microbiome science and translational medicine by revealing complex phage-host dynamics.