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Viral Structure00:56

Viral Structure

75.1K
Viruses are extraordinarily diverse in shape and size, but they all have several structural features in common. All viruses have a core that contains a DNA- or RNA-based genome. The core is surrounded by a protective coat of proteins called the capsid. The capsid is composed of subunits called capsomeres. The capsid and genome-containing core are together known as the nucleocapsid.
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Introduction to Virus01:28

Introduction to Virus

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Viruses are unique biological entities that blur the boundary between living and non-living systems. Although they lack cellular structure and metabolic processes, they can exhibit characteristics of life when infecting a host. Their defining feature is a nucleic acid core, composed of either DNA or RNA, encapsulated within a protein coat called a capsid. This simple structure allows them to invade host cells and use their machinery for replication efficiently.Viral Structure and...
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Size and Structure of Viral Genomes01:26

Size and Structure of Viral Genomes

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Viral genomes exhibit remarkable diversity in size, structure, and composition, influencing their replication strategies and interactions with host cells. These genomes consist of either DNA or RNA and may be linear or circular. Additionally, they can be single-stranded or double-stranded, with each configuration affecting how the virus propagates within a host. RNA viruses, for instance, generally have smaller genomes than DNA viruses, a factor that contributes to their high mutation rates and...
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DNA Helicases00:55

DNA Helicases

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DNA unwinding helicase enzymes are a type of motor protein. Motor proteins can translocate along filaments or polymers using energy generated from ATP hydrolysis. Helicases are involved in all the important cellular processes where DNA unwinding is required, such as DNA replication, repair, recombination, and transcription. They are present in all living organisms, but vary in their structure, function, and mechanism of action. For example, in prokaryotes, DnaB helicase binds and translocates...
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What are Viruses?00:50

What are Viruses?

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Overview
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Viruses with RNA Genomes01:29

Viruses with RNA Genomes

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RNA viruses are categorized into positive-strand, negative-strand, or double-stranded groups based on their genomic structure and replication mechanisms. This classification dictates how they exploit host cellular machinery for protein synthesis and replication. Some RNA viruses also utilize reverse transcription as part of their life cycle, further diversifying their replication strategies.Positive-Strand RNA VirusesPositive-strand RNA viruses have genomes that function directly as messenger...
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Related Experiment Video

Updated: Feb 28, 2026

Purification of Viral DNA for the Identification of Associated Viral and Cellular Proteins
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Purification of Viral DNA for the Identification of Associated Viral and Cellular Proteins

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Structure, Function and Inhibition of Helicases Involved in Virus Infection.

Gisoo Sarvari1, David D Boehr1

  • 1Department of Chemistry, The Pennsylvania State University, University Park, PA 16802, USA.

Biomolecules
|February 27, 2026
PubMed
Summary
This summary is machine-generated.

Viral helicases are essential ATPases for virus replication and pathogenicity. This review synthesizes their structure, function, and inhibition for antiviral drug development.

Keywords:
antiviral drug targetsgenome packaginghelicase inhibitorsviral gene expressionviral helicases

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Area of Science:

  • Virology
  • Biochemistry
  • Structural Biology

Background:

  • Viral helicases are crucial ATPases for viral replication, gene expression, and assembly.
  • They play a central role in viral pathogenicity and infection outcomes.

Purpose of the Study:

  • To compare viral helicase superfamilies, conserved motifs, and translocation models.
  • To analyze how viral helicases regulate viral replication, genome remodeling, and immune evasion.
  • To discuss targeting viral helicases for antiviral drug development.

Main Methods:

  • Review and synthesis of structural, biochemical, and virological data.
  • Analysis of mechanistic examples from diverse viral families (e.g., picornaviruses, flaviviruses, herpesviruses, coronaviruses).
  • Examination of antiviral screening and drug discovery efforts.

Main Results:

  • Viral helicase architecture, substrate specificity, and cofactors dictate diverse functions.
  • Helicases regulate replication fork progression, RNA metabolism, genome packaging, and immune evasion.
  • Mechanistic insights are provided for key viral families.

Conclusions:

  • Viral helicases are versatile enzymes critical for viral life cycles.
  • Understanding helicase function is key to developing effective antiviral strategies.
  • Targeting viral helicases presents opportunities and challenges for drug discovery, including resistance mechanisms.