Crystal structure of a DEAD box protein from the hyperthermophile Methanococcus jannaschii.

We have determined the structure of a DEAD box putative RNA helicase from the hyperthermophile Methanococcus jannaschii. Like other helicases, the protein contains two alpha/beta domains, each with a recA-like topology. Unlike other helicases, the protein exists as a dimer in the crystal. Through an interaction that resembles the dimer interface of insulin, the amino-terminal domain's 7-strand beta-sheet is extended to 14 strands across the two molecules. Motifs conserved in the DEAD box family cluster in the cleft between domains, and many of their functions can be deduced by mutational data and by comparison with other helicase structures. Several lines of evidence suggest that motif III Ser-Ala-Thr may be involved in binding RNA.

Interactions of three strands in joints made by RecA protein.

RecA protein from Escherichia coli has been used to form a triple-stranded DNA structure from either single-stranded M13 DNA or a single-stranded oligonucleotide plus a duplex oligonucleotide with a hairpin loop. The secondary structure of purified deproteinized triplex was examined by probing with DNase I, P1 nuclease, potassium permanganate, and diethyl pyrocarbonate. The two strands destined to form heteroduplex DNA showed the same patterns of chemical modification and enzymatic digestion as control duplex DNA, indicating that they formed a normal duplex substructure. However, the nascent outgoing strand showed properties consistent with a novel triplex structure: most of its purine residues, especially adenines, were hyperreactive to all probes. The patterns of digestion by DNase I and P1 nuclease indicated that the nascent outgoing strand was not a freely mobile or single-stranded branch but rather was still interacting with the newly formed heteroduplex DNA. On the basis of the planar base triads proposed previously (Rao et al., 1993) and energy minimization of a third strand in the major groove of B-form DNA, we derived a model that helps to rationalize the properties revealed by chemical and enzymatic probing.

Structural relationship of bacterial RecA proteins to recombination proteins from bacteriophage T4 and yeast.

RecA protein is essential in eubacteria for homologous recombination and promotes the homologous pairing and strand exchange of DNA molecules in vitro. Recombination proteins with weak sequence similarity to bacterial RecA proteins have been identified in bacteriophage T4, yeast, and other higher organisms. Analysis of the primary sequence relationships of DMC1 from Saccharomyces cerevisiae and UvsX of T4 relative to the three-dimensional structure of RecA from Escherichia coli suggests that both proteins are structural homologs of bacterial RecA proteins. This analysis argues that proteins in this group are members of a single family that diverged from a common ancestor that existed prior to the divergence of prokaryotes and eukaryotes.

The structure of the E. coli recA protein monomer and polymer.

The crystal structure of the recA protein from Escherichia coli at 2.3-A resolution reveals a major domain that binds ADP and probably single- and double-stranded DNA. Two smaller subdomains at the N and C termini protrude from the protein and respectively stabilize a 6(1) helical polymer of protein subunits and interpolymer bundles. This polymer structure closely resembles that of recA/DNA filaments determined by electron microscopy. Mutations in recA protein that enhance coprotease, DNA-binding and/or strand-exchange activity can be explained if the interpolymer interactions in the crystal reflect a regulatory mechanism in vivo.

Structure of the recA protein-ADP complex.

The recA protein catalyses the ATP-driven homologous pairing and strand exchange of DNA molecules. It is an allosteric enzyme: the ATPase activity is DNA-dependent, and ATP-bound recA protein has a high affinity for DNA, whereas the ADP-bound form has a low affinity. In the absence of ATP hydrolysis, recA protein can still promote homologous pairing, apparently through the formation of a triple-stranded intermediate. The exact role of ATP hydrolysis is not clear, but it presumably drives the triplex intermediate towards products. Here we determine the position of bound ADP diffused into the recA crystal. We show that only the phosphates are bound in the same way as in other NTPases containing the G/AXXXXGKT/S motif. We propose that recA protein may change its conformation upon ATP hydrolysis in a manner analogous to one such protein, the p21 protein from the ras oncogene. A model is presented to account for the allosteric stimulation of DNA binding by ATP. The mechanism by which nucleoside triphosphate hydrolysis is coupled to the binding of another ligand in recA protein and p21 may be typical of the large class of NTPases containing this conserved motif.