AI Article Synopsis
- The phage protein CII is key in deciding whether the temperate coliphage lambda will enter a lytic (destructive) or lysogenic (dormant) cycle by activating specific phage promoters (p(E), p(I), p(aQ)).
- CII is an unstable protein that gets quickly degraded by the host’s protease HflB, and this instability is crucial for its function in the lysis-lysogeny switch; its flexible C-terminal segment may be a target for degradation.
- Research reveals that certain regions of CII (specifically residues 70-82) are critical for forming the necessary tetramer structure, which enables operator binding and transcription activation, suggesting different
Article Abstract
A crucial element in the lysis-lysogeny decision of the temperate coliphage lambda is the phage protein CII, which has several interesting properties. It promotes lysogeny through activation of three phage promoters p(E), p(I) and p(aQ), recognizing a direct repeat sequence TTGCN6TTGC at each. The three-dimensional structure of CII, a homo-tetramer of 97 residue subunits, is unknown. It is an unstable protein in vivo, being rapidly degraded by the host protease HflB (FtsH). This instability is essential for the function of CII in the lysis-lysogeny switch. From NMR and limited proteolysis we show that about 15 C-terminal residues of CII are highly flexible, and may act as a target for proteolysis in vivo. From in vitro transcription, isothermal calorimetry and gel chromatography of CII (1-97) and its truncated fragments CIIA (4-81/82) and CIIB (4-69), we find that residues 70-81/82 are essential for (a) tetramer formation, (b) operator binding and (c) transcription activation. Presumably, tetramerization is necessary for the latter functions. Based on these results, we propose a model for CII structure, in which protein-protein contacts for dimer and tetramer formation are different. The implications of tetrameric organization, essential for CII activity, on the recognition of the direct repeat sequence is discussed.
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| http://dx.doi.org/10.1016/j.jmb.2004.09.098 | DOI Listing |
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