Lambda phage

(noun)

Enterobacteria phage λ (lambda phage, coliphage λ) is a bacterial virus, or bacteriophage, that infects the bacterial species Escherichia coli. This virus is temperate and may reside within the genome of its host through lysogeny.

Related Terms

Examples of Lambda phage in the following topics:

  • Bacteriophage Lambda as a Cloning Vector

    • Enterobacteria phage λ (lambda phage, coliphage λ) is a bacterial virus that infects the bacterial species Escherichia coli.
    • Enterobacteria phage λ (lambda phage, coliphage λ) is a bacterial virus, or bacteriophage, that infects the bacterial species Escherichia coli.
    • Lambda phage consists of a virus particle including a head (also known as a capsid), tail and tail fibers.
    • Usually, a "lytic cycle" ensues, where the lambda DNA is replicated many times and the genes for head, tail and lysis proteins are expressed.
    • Lambda phage has been of major importance in the study of specialized transduction.

  • Temperate Bacteriophages: Lambda and P1

    • When undergoing a lysogenic cycle, the phage genome exists as a plasmid in the bacterium, unlike other phages (e.g., the lambda phage) that integrate into the host DNA.
    • At around 93Kbp in length, the genome of the P1 phage is moderately large compared to the genomes of others, like T4 (169Kbp), lambda (48Kbp), and Ff (6.4Kbp).
    • Enterobacteria phage λ (lambda phage, coliphage λ) is a bacterial virus, or bacteriophage, that infects the bacterial species Escherichia coli.
    • Lambda phage consists of a virus particle including a head (also known as a capsid), a tail, and tail fibers.
    • Schematic representation of the insertion of the bacteriophage lambda.

  • The Lytic and Lysogenic Cycles of Bacteriophages

    • Lytic phages are more suitable for phage therapy.
    • Some lytic phages undergo a phenomenon known as lysis inhibition, where completed phage progeny will not immediately lyse out of the cell if extracellular phage concentrations are high.
    • Those phages able to undergo lysogeny are known as temperate phages.
    • An example of a bacteriophage known to follow the lysogenic cycle and the lytic cycle is the phage lambda of E. coli.
    • In the lytic cycle, the phage replicates and lyses the host cell.

  • Overview of Bacterial Viruses

    • Of these, at least 4950 phages (96%) have tails.
    • The dsDNA tailed phages, or Caudovirales, account for 95% of all the phages reported in the scientific literature, and possibly make up the majority of phages on the planet.
    • Those phages able to undergo lysogeny are known as temperate phages.
    • An example of a bacteriophage known to follow the lysogenic cycle and the lytic cycle is the phage lambda of E. coli.
    • An altogether different phage type, the filamentous phages, make the host cell continually secrete new virus particles.

  • Mu: A Double-Stranded Transposable DNA Bacteriophage

    • Bacteriophage Mu, or phage Mu, is a temperate bacteriophage, a type of virus that infects bacteria.
    • All of the known temperate phages employ one of only three different systems for their lysogenic cycle: lambda-like integration/excision, Mu-like transposition, or the plasmid-like partitioning of phage N15.
    • Mu phage transposition is the best known example of replicative transposition.
    • Structural overview of the T4 phage, from the same family (Myoviridae) as Mu bacteriophage.

  • Phage Display

    • Phage display is a laboratory tool based on cloning DNA sequences into a phage which presents proteins encoded by that DNA on its surface.
    • When the sub-components of the phage are produced, they self-assemble to form new phage particles.
    • This inherent property of phages is the basis for the phage display technology.
    • Phage display technology is the process of inserting new genetic material into a phage gene.
    • Phage display begins by inserting a diverse set of genes into the phage genome with each phage receiving a different gene.

  • Batch Culture of Bacteriophages

    • Bacteriophage cultures require host cells in which the virus or phage multiply.
    • Virus or phage cultures require host cells in which to multiply.
    • An altogether different phage type, the filamentous phages, make the host cell continually secrete new virus particles.
    • Budding is associated with certain Mycoplasma phages.
    • Virus or phage cultures require host cells in which to multiply.

  • The Lambda Limit

  • Viral Roles in Ecosystems

    • As mentioned, marine viruses are mostly bacteriophages, or phages.
    • Phages therefore are found only within environments that contain bacteria.
    • As a consequence, phages are found almost everywhere.
    • As a rule of thumb, many phage biologists expect that phage population densities will exceed bacterial densities by a ratio of 10:1 or more (VBR or virus-to-bacterium ratio).
    • Phage-ecological interactions are also qualitatively diverse: there are huge numbers of environment types, bacterial-host types, and also individual phage types.

  • Double-Stranded DNA Bacteriophages

    • The dsDNA tailed phages, or Caudovirales, account for 95% of all known phages and possibly make up the majority of phages on the planet.
    • The Double-Stranded DNA (dsDNA) tailed phages, or Caudovirales, account for 95% of all the phages reported in the scientific literature, and possibly make up the majority of phages on the planet.
    • The phages have a head of approximately 55 nm in diameter, loaded with genetic material.
    • In the lower micrograph, PAD25 is adhering to bacterial cell debris, and two phages have lost their heads.
    • All phages were classified as Siphoviruses based on their morphology.