8.7: Phage Can Integrate Their DNA Into the Bacterial Chromosome

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We have seen how a phage can infect bacterial cells and co-opt the host’s bacterial metabolic machinery to reproduce itself, eventually lysing the bacterium and releasing the phage. This lytic activity of infection is one of two alternate phage life cycles. Lysogeny is the other lifecycle pathway for bacteriophage.

Lysogeny typically begins when the phage DNA is incorporated (i.e., is spliced) into the host bacterium’s genome. There it will replicate along with the host’s chromosome during rounds of binary fission. Upon excision, usually when the bacterium is under stress (e.g., nutrientdeprivation), the phage DNA can reenter the lytic pathway, reproducing and lysing the host cell.

During excision, phage DNA can pick up bacterial DNA (i.e., genes) that will then be transferred to a new host cell in a subsequent infection. The transfer of genes from one bacterial cell to another in this way is called bacterial transduction. Esther and Joshua Lederberg studied the lysogenic activity of lambda phage (λ phage) in E. coli, showing that— like conjugation—bacterial transduction by λ phage results in lateral gene transfer between bacteria. In general, lateral gene transfer increases genetic diversity in bacteria (and, in fact, in many prokaryotic and eukaryotic organisms). We will see more examples of lateral gene transfer in later chapters. The events of lysogenic phage infection are illustrated in Figure 8.23.

Screen Shot 2022-05-19 at 4.44.21 PM.png — Figure 8.23: The lysogenic life cycle of phage

Recall that Joshua Lederberg shared a Nobel Prize with George Beadle and Edward Tatum for proposing the one-gene/one-enzyme hypothesis (eventually the one-gene/one polypeptide relationship). Esther Lederberg had studied earlier with Beadle, Tatum, and her husband at Stanford University in 1944, and many credit her with helping her mentors win that 1958 Nobel Prize. In her own right, she held adjunct or directorial positions at the University of Wisconsin–Madison and at Stanford University, where her other seminal research included the discovery of lambda phage (1950), the invention of the replica-plating technique (1951), the demonstration of lambda-phage transduction in E. coli, and the discovery of the fertility factor in E. coli. See Esther Lederberg's Accomplishments to explore why she was never a faculty member or a Nobel laureate.

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