The bacteriophage 0X174 origin for (+) strand DNA synthesis, when inserted in a plasmid, is in vivo a substrate for the initiator A protein, that is produced by infecting phages. The result of this interaction is the packaging of single-stranded plasmid DNA into preformed phage coats. These plasmid particles can transduce 0X-sensitive cells; however, the transduction efficiency depends strongly on the presence in the packaged DNA strand of an initiation signal for complementary strand DNA synthesis. A plasmid with the complementary (-) strand origin of 0X inserted in the same strand as the viral (+) origin transduces 50-100 times more efficient than the same plasmid without the (-) origin of 0X. The transduction efficiency of such a particle is comparable to the infection efficiency of the phage particle. It is shown that in this system the 0X (-) origin can be replaced by the complementary strand origins of the bacteriophages G4 and M13. We have used this system to isolate sequences, from E. coli plasmids (pACYC177, CloDF13, miniF and OriC) and from the E. coli chromosome that can function as initiation signals for the conversion of single-stranded plasmid DNA to double-stranded DNA. All isolated origins were found to be dependent for their activity on the dnaB, dnaC and dnaG proteins. We conclude that these signals were all primosome-dependent origins and that primosome priming is the major mechanism for initiation of the lagging strand DNA synthesis in E. coli. The assembly of the primosome depends on the sequence-specific interaction of the n' protein with single-stranded DNA. We have used the isolated sequences to deduce a consensus recognition sequence for the n' protein. The role of a possible secondary structure in this sequence is discussed.
Transgenic tomato plants that constitutively express a foreign plastocyanin gene were used to study protein transport in different tissues. Normally expression of endogenous plastocyanin genes in plants is restricted to photosynthetic tissues only, whereas this foreign plastocyanin protein is found to be present in all tissues examined. The protein is transported into the local plastids in these tissues and it is processed to the mature size. We conclude that plastids of developmentally different tissues are capable of importing precursor proteins that are normally not found in these tissues. Most likely such plastids, though functionally and morphologically differentiated, have similar or identical protein import mechanisms when compared to the chloroplasts in green tissue.
Incubation of phi X174 replication form I DNA with the A* protein of phi X174 in the presence of MN2+ results in the formation of three different types of DNA molecules: open circular form DNA (RFII), linear form DNA (RFIII) and the relaxed covalently closed form DNA (RFIV). The RFII and RFIII DNAs are shown to be A* protein-DNA complexes by electron microscopy using the protein labeling technique of Wu and Davidson (1). The linear double-stranded RFIII DNA molecule carries at one end a covalently attached A* protein whereas at the other end of the molecule the single-stranded termini are covalently linked to each other. The structure of the RFIII DNA shows its way of formation. The described properties of the A* protein indicate the way the larger A protein functions in the termination step of the rolling-circle type of phi X174 DNA replication.
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