Normal terC-region of the Bacillus subtilis chromosome acts in a polar manner to arrest the clockwise replication fork.

A procedure is described for relocating a functional terC-region to various sites on the Bacillus subtilis chromosome, and in alternative orientations. The relocated terC-region comprised the IRR-rtp portion of the chromosome contained within a 1.75 x 10(3) base-pair segment of DNA. This segment was first cloned into the Tn 917 vector pTV20 in both orientations, and the two new plasmids used for inserting the terC-region into chromosomal copies of Tn 917. When relocated to the pyr and metD loci (139 degrees and 100 degrees positions on the 360 degrees map) it was found that clockwise replication fork arrest occurred only when the IRR-rtp (or terC-) region was oriented, in relation to the direction of approach of the fork, in the same way as in the wild-type strain. Thus, the complete IRR when located in the chromosome, and apparently made up of opposing terminators which might enable it to function in both orientations, is polar in its action. Of the two inverted repeats present in the IRR, it appears that IRI is functional in the chromosome, but not IRII.

Relocation of the replication terminus, terC, of Bacillus subtilis to a new chromosomal site.

The terC-deletion strain of Bacillus subtilis 168, SU153 [Iismaa and Wake, J. Mol. Biol. 195 (1987) 299-310] was used for the re-insertion of a 1.75-kb segment of DNA containing terC at a site approx. 25 kb from its original position. The relocated terC in the new strain, SU160, was oriented normally with respect to the approaching clockwise replication fork, and was positioned such that this fork was the first to reach it. The relocated terC was effective in causing arrest of the clockwise fork, as evidenced by the appearance of a unique DNA species with a characteristic mobility in agarose gel electrophoresis and with a predicted single-strand composition. Thus, the previously cloned 1.75-kb terC-containing segment [Smith et al., Gene 38 (1985) 9-17] has not been altered with respect to TerC function and contains sufficient sequence for this function. The findings reported here provide the opportunity for establishing the minimal and essential sequence features of terC, and for examining its possible polarity of action in causing fork arrest.

Sequence features of the replication terminus of the Bacillus subtilis chromosome.

The sequence of 1267 nucleotides spanning the replication terminus, terC, of the Bacillus subtilis 168 chromosome has been determined. The site of arrest of the clockwise fork, which defines terC, has been localized to a 30-nucleotide portion (approximately) within this sequence. The arrest site occurs in an A + T-rich region between two open reading frames and very close to one of two imperfect inverted repeats (47-48 nucleotides each) which are separated by 59 nucleotides. The closeness of approach of the arrested clockwise fork to the first imperfect inverted repeat encountered in this region raises the possibility of a role for the inverted repeats in the mechanism of fork arrest.

Breakdown and quantitation of the forked termination of replication intermediate of Bacillus subtilis.

Using a procedure that minimizes shear forces, the BamHI-derived forked termination of replication intermediate of Bacillus subtilis, called band I DNA, can be extracted with little or no accompanying band II DNA. It has been shown that band II DNA is a product of band I breakdown. Nuclease P1-mediated breakdown of the forked band I DNA proceeds in two steps. The first causes the release of one of the arms as band II DNA; in the second step, the remaining arm is cleaved away to yield the free stem. It is concluded that band I represents the primary termination of replication intermediate. A quantitative assessment of the level of band I in DNA from cells of the merodiploid strain, GSY1127, growing at different rates has been made. For cells grown in a minimal medium, at least, the experimentally measured level of band I is of the order (approx. 60%) of that predicted for a complete block to movement of the clockwise fork at the replication terminus, terC.