Crystal structure of a Flp recombinase-Holliday junction complex: assembly of an active oligomer by helix swapping.

The crystal structure of a Flp recombinase tetramer bound to a Holliday junction intermediate has been determined at 2.65 A resolution. Only one of Flp's two domains, containing the active site, is structurally related to other lambda integrase family site-specific recombinases, such as Cre. The Flp active site differs, however, in that the helix containing the nucleophilic tyrosine is domain swapped, such that it cuts its DNA target in trans. The Flp tetramer displays pseudo four-fold symmetry matching that of the square planar Holliday junction substrate. This tetramer is stabilized by additional novel trans interactions among monomers. The structure illustrates how mechanistic unity is maintained on a chemical level while allowing for substantial variation on the structural level within a family of enzymes.

Establishment and characterization of immortalized human cell lines from prostatic carcinoma and benign prostatic hyperplasia.

New human prostate cell lines were developed from prostatic carcinoma (BRF-41T) and BPH (BRF-55T). Primary cultures were initiated from cellular outgrowths of explanted tissues. A serum-free medium, BRFF-HPC1, was developed for growing human prostatic cancer cells. Cell strains were immortalized with pRSV-T plasmid to generate permanent cell lines that exhibited an epithelial morphology. Both cell lines expressed the epithelial cell markers, cytokeratins 8 and 18 as well as the prostatic marker, PSA, and the androgen receptor gene. They possess the H-ras, K-ras, and p53 genes. We hope that these new human prostatic cell lines will be useful as in vitro models for cancer research.

Blocked RecA protein-mediated DNA strand exchange reactions are reversed by the RuvA and RuvB proteins.

RecA protein is unable to complete a DNA strand exchange reaction between a circular single-stranded DNA and a linear duplex DNA substrate with heterologous sequences of 375 base pairs at the distal end. Instead, it generates a branched intermediate in which strand exchange has proceeded up to the homology/heterology junction. Addition of the RuvA and RuvB proteins to these stalled intermediates leads to the rapid conversion of intermediates back to the original substrates. The reversal reaction is initiated at the branch, and the hybrid DNA is unwound in the direction opposite to that of the RecA reaction that created it. Under optimal conditions the rate of the reaction exhibits only a modest dependence on the length of hybrid DNA that must be unwound. Products of the reversal reaction are detected within minutes after addition of RuvAB, and appear with an apparent first order progress curve, exhibiting a t1/2 in the range of 6-12 min under optimal conditions. Few molecules that have undergone only partial reversal are detected. This suggests that the assembly or activation of RuvAB on the branched substrate is rate-limiting, while any migration of RuvAB on the DNA to effect unwinding of the hybrid DNA (and reformation of substrate DNA) is very fast. The results are discussed in context of the role of RuvA and RuvB proteins in recombinational DNA repair. We suggest that one function of the RuvAB proteins is to act as an antirecombinase, to eliminate intragenomic crossovers between homologous segments of the bacterial chromosome that might otherwise lead to deleterious inversions or deletions.

RuvA and RuvB proteins facilitate the bypass of heterologous DNA insertions during RecA protein-mediated DNA strand exchange.

RecA protein-mediated DNA strand exchange between circular single-stranded DNA and linear duplex DNA readily bypasses short (up to 100 base pairs) heterologous inserts in one of the DNA substrates. Larger heterologous inserts are bypassed with decreasing efficiency, and inserts larger than 200 base pairs substantially block RecA-mediated DNA strand exchange. The RuvA and RuvB proteins dramatically facilitate the bypass of larger heterologous inserts. When the RuvA and RuvB proteins are added to an ongoing RecA protein-mediated strand exchange reaction, interior heterologous inserts of 1 kilobase pair are bypassed at significant frequencies. The RuvA, RuvB, and RecA proteins are all required for this activity. Bypass occurs only when homologous sequences are present on both sides of the insert. When the heterologous insert is positioned at either end of the linear duplex substrate, the RuvA and RuvB proteins do not significantly increase product formation in RecA protein-mediated DNA strand exchange reactions. The results suggest an important role for RuvA and RuvB in the bypass of DNA structural barriers during recombinational DNA repair.