lysogenic cycle

It shows a lytic cycle and a lysogenic cycle.

In contrast, the lysogenic cycle does not result in immediate lysing of the host cell.

Transduction happens through either the lytic cycle and the lysogenic cycle.

Temperate phages can lead to both advantages and disadvantages for their hosts via the lysogenic cycle.

As the lysogenic cycle allows the host cell to continue to survive and reproduce, the virus is reproduced in all of the cell's offspring.

Bacteriophages may have a lytic cycle or a lysogenic cycle, and a few viruses are capable of carrying out both.

There are three classes of genes in the phage genome that regulate whether the lytic or lysogenic cycles will emerge.

A productive infectious cycle begins before a lysogenic cycle establishes the virus in the infected bacteria.

Lysogenic cycles can also occur in eukaryotes, although the method of DNA incorporation is not fully understood.

Temperate phages (such as lambda phage) can reproduce using the lytic or lysogenic cycle.

During the lysogenic cycle, the virus genome is incorporated as prophage and a repressor prevents viral replication.

This is in contrast to the lytic and lysogenic cycles of other phages where the host is killed when virions are released.

In contrast to virion release, phages displaying a lysogenic cycle do not kill the host but, rather, become long-term residents as prophage.

The lytic cycle is one of the two cycles of viral reproduction, the other being the lysogenic cycle.

Some viruses undergo a lysogenic cycle where the viral genome is incorporated by genetic recombination into a specific place in the host's chromosome.

In the lysogenic cycle, the phage DNA first integrates into the bacterial chromosome to produce the prophage.

If the phage is present, indicator strains will become infected and go through the normal lysogenic cycle while the plates incubate, and then undergo lysis.

Via the lysogenic cycle, the bacteriophage's genome is not expressed and is instead integrated into the bacteria's genome to form the prophage.

A bacteriophage moron is an extra gene in prophage genomes that do not have a phage function in the lysogenic cycle.

In the lysogenic cycle the phage genome replicates with the rest of the bacterial genome and is transmitted to daughter cells at each subsequent cell division.

Lysogens can remain in the lysogenic cycle for many generations but can switch to the lytic cycle at any time via a process known as induction.

An example of a bacteriophage known to follow the lysogenic cycle and the lytic cycle is the phage lambda of E. coli.

He identified new bacterial genes influencing the decision between the lysogenic cycle and lysis and he analyzed mutants of RNA polymerase.

The key difference between the lytic cycle and the lysogenic cycle is that the lysogenic cycle does not lyse the host cell.

Cro dominates the repressor site (see "Repressor" section), repressing synthesis from the P promoter (which is a promoter of the lysogenic cycle).