Highly organized DnaA–oriC complexes recruit the single-stranded DNA for replication initiation

In Escherichia coli, the replication origin oriC consists of two functional regions: the duplex unwinding element (DUE) and its flanking DnaA-assembly region (DAR). ATP-DnaA molecules multimerize on DAR, unwinding DUE for DnaB helicase loading. However, DUE-unwinding mechanisms and functional structures in DnaA–oriC complexes supporting those remain unclear. Here, using various in vitro reconstituted systems, we identify functionally distinct DnaA sub-complexes formed on DAR and reveal novel mechanisms in DUE unwinding. The DUE-flanking left-half DAR carrying high-affinity DnaA box R1 and the ATP-DnaA-preferential DnaA box R5, τ1-2 and I1-2 sites formed a DnaA sub-complex competent in DUE unwinding and ssDUE binding, thereby supporting basal DnaB loading activity. This sub-complex is further subdivided into two; the DUE-distal DnaA sub-complex formed on the ATP–DnaA-preferential sites binds ssDUE. Notably, the DUE-flanking, DnaA box R1–DnaA sub-complex recruits DUE to the DUE-distal DnaA sub-complex in concert with a DNA-bending nucleoid protein IHF, thereby promoting DUE unwinding and binding of ssDUE. The right-half DAR–DnaA sub-complex stimulated DnaB loading, consistent with in vivo analyses. Similar features are seen in DUE unwinding of the hyperthermophile, Thermotoga maritima, indicating evolutional conservation of those mechanisms

PaperClip:rapid multi-part DNA assembly from existing libraries

Assembly of DNA ‘parts ’ to create larger constructs is an essential enabling technique for bioengineer-ing and synthetic biology. Here we describe a sim-ple method, PaperClip, which allows flexible assem-bly of multiple DNA parts from currently existing libraries cloned in any vector. No restriction en-zymes, mutagenesis of internal restriction sites, or reamplification to add end homology are required. Order of assembly is directed by double stranded oligonucleotides––‘Clips’. Clips are formed by lig-ation of pairs of oligonucleotides corresponding to the ends of each part. PaperClip assembly can be performed by polymerase chain reaction or by cell extract-mediated recombination. Once multi-use Clips have been prepared, assembly of at least six DNA parts in any order can be accomplished with high efficiency within several hours

Integration host factor: A protein for all reasons

Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/27063/1/0000053.pd

π Protein- and ATP-dependent transitions from ‘closed’ to ‘open’ complexes at the γ ori of plasmid R6K

R6K-encoded π protein can bind to the seven, 22 bp tandem iterons of the γ origin. In this work, we use a variant of π, His-π·F107S, that is hyperactive in replication. In vitro, His-π·F107S-dependent local DNA melting (open complex formation) occurs in the absence of host proteins (IHF/HU or DnaA) and it is positioned in the A + T-rich region adjacent to iterons. Experiments described here examine the effects of ATP, Mg(2+) and temperature on the opening reaction. We show that the opening of the γ origin can occur in the presence of ATP as well as AMP-PCP (a non-hydrolyzable ATP analog). This suggests that, for γ origin, ATP hydrolysis may be unnecessary for open complex formation facilitated by His-π·F107S. In the absence of ATP or Mg(2+), His-π·F107S yielded data suggestive of distortions in the iteron attributable to DNA bending rather than DNA melting. Our findings also demonstrate that ATP and π stimulate open complex formation over a wide range of temperatures, but not at 0°C. These and other results indicate that ATP and/or Mg(2+) are not needed for His-π·F107S binding to iterons and that ATP effects an allosteric change in the protein bound to γ origin

Integration host factor of Escherichia coli reverses the inhibition of R6K plasmid replication by pi initiator protein

Integration host factor (IHF) protein is the only host-encoded protein known to bind and to affect replication of the gamma origin of Escherichia coli plasmid R6K. We examined the ability of R6K origins to replicate in cells lacking either of the two subunits of IHF. As shown previously, the gamma origin cannot replicate in IHF-deficient cells. However, this inability to replicate was relieved under the following conditions: underproduction of the wild-type pi replication protein of R6K or production of normal levels of mutant pi proteins which exhibit relaxed replication control. The copy number of plasmids containing the primary R6K origins (alpha and beta) is substantially reduced in IHF-deficient bacteria. Furthermore, replication of these plasmids is completely inhibited if the IHF-deficient strains contain a helper plasmid producing additional wild-type pi protein. IHF protein has previously been shown to bind to two sites within the gamma origin. These sites flank a central repeat segment which binds pi protein. We propose a model in which IHF binding to its sites reduces the replication inhibitor activity of pi protein at all three R6K origins.</jats:p