TY - JOUR
T1 - Steps in the stabilization of newly packaged DNA during phage P22 Morphogenesis
AU - Strauss, Harlee
AU - King, Jonathan
N1 - Funding Information:
We thank Erika Hartwieg for her expert assistance with the electron microscopy and Jennice Phillips for her typing and editing skills. This work was supported by National Institutes of Health grant no. GM17980-14.
PY - 1984/2/5
Y1 - 1984/2/5
N2 - The protein products of three adjacent P22 genes, 4, 10 and 26, are required for the stabilization of DNA newly packaged into P22 phage capsids. We have isolated unstable DNA containing capsids from cells infected with mutants defective in these genes. All three classes could be converted into mature phage in vitro, confirming that they represent intermediates in particle maturation. The first of the three proteins to add to the newly filled capsids is gp4, followedby gp10 and gp26. The active form of gp4 sediments at 3 S, while the active forms of both gp10 and gp26 sediment at 5 S. These soluble subunits appear to polymerize onto the newly filled capsids to form the neck of the mature phage, the channel for DNA injection. Since gp4 is the first protein to act after DNA packaging, the unstable DNAcontaining capsids from 4--infected cells must represent the direct product of the packaging of DNA into procapsids. The major fraction of these capsids lost activity with a half-life of 1·1 minutes at 23°C, though they were much more stable at 0°C. Electron microscopic observations indicated that the loss of activity was due to the DNA exiting from the incomplete capsids. The marginal stability of the condensed DNA molecules within capsids is consistent with models of ATP-driven condensation and spontaneous DNA ejection. The basis of the stability of these highly condensed molecules remains to be determined.
AB - The protein products of three adjacent P22 genes, 4, 10 and 26, are required for the stabilization of DNA newly packaged into P22 phage capsids. We have isolated unstable DNA containing capsids from cells infected with mutants defective in these genes. All three classes could be converted into mature phage in vitro, confirming that they represent intermediates in particle maturation. The first of the three proteins to add to the newly filled capsids is gp4, followedby gp10 and gp26. The active form of gp4 sediments at 3 S, while the active forms of both gp10 and gp26 sediment at 5 S. These soluble subunits appear to polymerize onto the newly filled capsids to form the neck of the mature phage, the channel for DNA injection. Since gp4 is the first protein to act after DNA packaging, the unstable DNAcontaining capsids from 4--infected cells must represent the direct product of the packaging of DNA into procapsids. The major fraction of these capsids lost activity with a half-life of 1·1 minutes at 23°C, though they were much more stable at 0°C. Electron microscopic observations indicated that the loss of activity was due to the DNA exiting from the incomplete capsids. The marginal stability of the condensed DNA molecules within capsids is consistent with models of ATP-driven condensation and spontaneous DNA ejection. The basis of the stability of these highly condensed molecules remains to be determined.
UR - http://www.scopus.com/inward/record.url?scp=0021329694&partnerID=8YFLogxK
U2 - 10.1016/S0022-2836(84)80021-2
DO - 10.1016/S0022-2836(84)80021-2
M3 - Article
C2 - 6363718
AN - SCOPUS:0021329694
SN - 0022-2836
VL - 172
SP - 523
EP - 543
JO - Journal of Molecular Biology
JF - Journal of Molecular Biology
IS - 4
ER -