A structural solution for the DNA polymerase lambda-dependent repair of DNA gaps with minimal homology

Human DNA polymerase lambda (Pol lambda) is a family X member with low frameshift fidelity that has been suggested to perform gap-filling DNA synthesis during base excision repair and during repair of broken ends with limited homology. Here, we present a 2.1 A crystal structure of the catalytic core of Pol lambda in complex with DNA containing a two nucleotide gap. Pol lambda makes limited contacts with the template strand at the polymerase active site, and superimposition with Pol beta in a ternary complex suggests a shift in the position of the DNA at the active site that is reminiscent of a deletion intermediate. Surprisingly, Pol lambda can adopt a closed conformation, even in the absence of dNTP binding. These observations have implications for the catalytic mechanism and putative DNA repair functions of Pol lambda.     

Crystal structure of the C-terminal domain of human DNA primase large subunit

DNA polymerases cannot synthesize DNA without a primer, and DNA primase is the only specialized enzyme capable of de novo synthesis of short RNA primers. In eukaryotes, primase functions within a heterotetrameric complex in concert with a tightly bound DNA polymerase α (Pol α). In humans, the Pol α part is comprised of a catalytic subunit (p180) and an accessory subunit B (p70), and the primase part consists of a small catalytic subunit (p49) and a large essential subunit (p58). The latter subunit participates in primer synthesis, counts the number of nucleotides in a primer, assists the release of the primer-template from primase and transfers it to the Pol α active site. Recently reported crystal structures of the C-terminal domains of the yeast and human enzymes’ large subunits provided critical information related to their structure, possible sites for binding of nucleotides and template DNA, as well as the overall organization of eukaryotic primases. However, the structures also revealed a difference in the folding of their proposed DNA-binding fragments, raising the possibility that yeast and human proteins are functionally different. Here we report new structure of the C-terminal domain of the human primase p58 subunit. This structure exhibits a fold similar to a fold reported for the yeast protein but different than a fold reported for the human protein. Based on a comparative analysis of all three C-terminal domain structures, we propose a mechanism of RNA primer length counting and dissociation of the primer-template from primase by a switch in conformation of the ssDNA-binding region of p58.     

Conformational flexibility of PEP mutase

Previous work has indicated that PEP mutase catalyzes the rearrangement of phosphoenolpyruvate to phosphonopyruvate by a dissociative mechanism. The crystal structure of the mutase with Mg(II) and sulfopyruvate (a phosphonopyruvate analogue) bound showed that the substrate is anchored to the active site by the Mg(II), and shielded from solvent by a large loop (residues 115-133). Here, the crystal structures of wild-type and D58A mutases, in the apo state and in complex with Mg(II), are reported. In both unbound and Mg(II)-bound states, the active site is accessible to the solvent. The loop (residues 115-133), which in the enzyme-inhibitor complexes covers the active site cavity, is partially disordered or adopts a conformation that allows access to the cavity. In the apo state, the residues associated with Mg(II) binding are poised to accept the metal ion. When Mg(II) binds, the coordination is the same as that previously observed in the enzyme-Mg(II) sulfopyruvate complex, except that the coordination positions occupied by two ligand oxygen atoms are occupied by two water molecules. When the loop opens, three key active site residues are displaced from the active site, Lys120, Asn122, and Leu124. Lys120 mediates Mg(II) coordination. Asn122 and Leu124 surround the transferring phosphoryl group, and thus prevent substrate hydrolysis. Amino acid replacement of any one of these three loop residues results in a significant loss of catalytic activity. It is hypothesized that the loop serves to gate the mutase active site, interconverting between an open conformation that allows substrate binding and product release and a closed conformation that separates the reaction site from the solvent during catalysis.