Highly conserved amino acids in Pax and Ets proteins are required for DNA binding and ternary complex assembly

Combinatorial association of DNA-binding proteins on composite binding sites enhances their nucleotide sequence specificity and functional synergy. As a paradigm for these interactions, Pax-5 (BSAP) assembles ternary complexes with Ets proteins on the B cell-specific mb-1 promoter through interactions between their respective DNA-binding domains. Pax-5 recruits Ets-1 to bind the promoter, but not the closely related Ets protein SAP1a. Here we show that, while several different mutations increase binding of SAP1a to an optimized Ets binding site, only conversion of Val68 to an acidic amino acid facilitates ternary complex assembly with Pax-5 on the mb-1 promoter. This suggests that enhanced DNA binding by SAP1a is not sufficient for recruitment by Pax-5, but instead involves protein–protein interactions mediated by the acidic side chain. Recruitment of Ets proteins by Pax-5 requires Gln22 within the N-terminal β-hairpin motif of its paired domain. The β-hairpin also participates in recognition of a subset of Pax-5-binding sites. Thus, Pax-5 incorporates protein–protein interaction and DNA recognition functions in a single motif. The Caenorhabditis elegans Pax protein EGL-38 also binds specifically to the mb-1 promoter and recruits murine Ets-1 or the C.elegans Ets protein T08H4.3, but not the related LIN-1 protein. Together, our results define specific amino acid requirements for Pax–Ets ternary complex assembly and show that the mechanism is conserved between evolutionarily related proteins of diverse animal species. Moreover, the data suggest that interactions between Pax and Ets proteins are an important mechanism that regulates fundamental biological processes in worms and humans.     

Structure and function of the regulatory C-terminal HRDC domain from Deinococcus radiodurans RecQ

RecQ helicases are critical for maintaining genome integrity in organisms ranging from bacteria to humans by participating in a complex network of DNA metabolic pathways. Their diverse cellular functions require specialization and coordination of multiple protein domains that integrate catalytic functions with DNA–protein and protein–protein interactions. The RecQ helicase from Deinococcus radiodurans (DrRecQ) is unusual among RecQ family members in that it has evolved to utilize three ‘Helicase and RNaseD C-terminal’ (HRDC) domains to regulate its activity. In this report, we describe the high-resolution structure of the C-terminal-most HRDC domain of DrRecQ. The structure reveals unusual electrostatic surface features that distinguish it from other HRDC domains. Mutation of individual residues in these regions affects the DNA binding affinity of DrRecQ and its ability to unwind a partial duplex DNA substrate. Taken together, the results suggest the unusual electrostatic surface features of the DrRecQ HRDC domain may be important for inter-domain interactions that regulate structure-specific DNA binding and help direct DrRecQ to specific recombination/repair sites.     

Investigation of site-specific DNA binding with nicking endonuclease Nt.BspD6I at single molecule level by atomic force microscopy

Nicking endonuclease Nt.BspD6I is a heterodimeric restriction endonuclease, one subunit of which exhibits specific nicking activity. It gets bound to double-stranded DNA and makes a break (nick) in one chain at a distance of 4 nucleotides from the binding site. In this work, for visualization of the specific binding and protein landing site an atomic force microscopy was used. In five minutes after incubation of DNA solution with nicking endonuclease, the DNA molecules with associated proteins which located at the expected binding site and "shared" DNA strand into two segments (approximately, 1/3 and 2/3 of length) were observed in the images. In addition, near the binding site DNA molecule had a height corresponding to a single-stranded DNA molecule, which was in good agreement with single-stranded cleavage by nickase in the course of complex formation.     

Crystal structures of the structure‐selective nuclease Mus81‐Eme1 bound to flap DNA substrates

The Mus81‐Eme1 complex is a structure‐selective endonuclease with a critical role in the resolution of recombination intermediates during DNA repair after interstrand cross‐links, replication fork collapse, or double‐strand breaks. To explain the molecular basis of 3′ flap substrate recognition and cleavage mechanism by Mus81‐Eme1, we determined crystal structures of human Mus81‐Eme1 bound to various flap DNA substrates. Mus81‐Eme1 undergoes gross substrate‐induced conformational changes that reveal two key features: (i) a hydrophobic wedge of Mus81 that separates pre‐ and post‐nick duplex DNA and (ii) a “5′ end binding pocket” that hosts the 5′ nicked end of post‐nick DNA. These features are crucial for comprehensive protein‐DNA interaction, sharp bending of the 3′ flap DNA substrate, and incision strand placement at the active site. While Mus81‐Eme1 unexpectedly shares several common features with members of the 5′ flap nuclease family, the combined structural, biochemical, and biophysical analyses explain why Mus81‐Eme1 preferentially cleaves 3′ flap DNA substrates with 5′ nicked ends.     

Site-specific interaction of vaccinia virus topoisomerase I with duplex DNA. Minimal DNA substrate for strand cleavage in vitro.

Purified vaccinia virus DNA topoisomerase I forms a cleavable complex with duplex DNA at a conserved sequence element 5'(C/T)CCTTdecreases in the incised DNA strand. DNase I footprint studies show that vaccinia topoisomerase protects the region around the site of covalent adduct formation from nuclease digestion. On the cleaved DNA strand, the protected region extends from +13 to -13 (+1 being the site of cleavage). On the noncleaved strand, the protected region extends from +13 to -9. Similar nuclease protection is observed for a mutant topoisomerase (containing a Tyr ---- Phe substitution at the active site amino acid 274) that is catalytically inert and does not form the covalent intermediate. Thus, vaccinia topoisomerase is a specific DNA binding protein independent of its competence in transesterification. By studying the cleavage of a series of 12-mer DNA duplexes in which the position of the CCCTTdecreases motif within the substrate is systematically phased, the "minimal" substrate for cleavage has been defined; cleavage requires six nucleotides upstream of the cleavage site and two nucleotides downstream of the site. An analysis of the cleavage of oligomer substrates mutated singly in the CCCTT sequence reveals a hierarchy of mutational effects based on position within the pentamer motif and the nature of the sequence alteration.