Abstract
In Escherichia coli, ATP-DnaA multimers formed on the replication origin oriC promote duplex unwinding, which leads to helicase loading. Based on a detailed functional analysis of the oriC sequence motifs, we previously proposed that the left half of oriC forms an ATP-DnaA subcomplex competent for oriC unwinding, whereas the right half of oriC forms a distinct ATP-DnaA subcomplex that facilitates helicase loading. However, the molecular basis for the functional difference between these ATP-DnaA subcomplexes remains unclear. By analyzing a series of novel DnaA mutants, we found that structurally distinct DnaA multimers form on each half of oriC. DnaA AAA+ domain residues Arg-227 and Leu-290 are specifically required for oriC unwinding. Notably, these residues are required for the ATP-DnaA-specific structure of DnaA multimers in complex with the left half of oriC but not for that with the right half. These results support the idea that the ATP-DnaA multimers formed on oriC are not uniform and that they can adopt different conformations. Based on a structural model, we propose that Arg-227 and Leu-290 play a crucial role in inter-ATP-DnaA interaction and are a prerequisite for the formation of unwinding-competent DnaA subcomplexes on the left half of oriC. These residues are not required for the interaction with DnaB, nucleotide binding, or regulatory DnaA-ATP hydrolysis, which further supports their important role in inter-DnaA interaction. The corresponding residues are evolutionarily conserved and are required for unwinding in the initial complexes of Thermotoga maritima, an ancient hyperthermophile. Therefore, our findings suggest a novel and common mechanism for ATP-DnaA-dependent activation of initial complexes.
Highlights
Multiple DnaA molecules form highly ordered complexes on the origin DNA to initiate chromosomal replication
In this study, we revealed that specific tmaDnaA residues within ATP-DnaAspecific interactive locus for DUE unwinding (AID)-1 and AID-2 are crucial for duplex unwinding element (DUE) unwinding
We revealed that E. coli DnaA Arg-227 and Leu-290 play a specific role in DUE unwinding and ssDUE binding
Summary
Multiple DnaA molecules form highly ordered complexes on the origin DNA to initiate chromosomal replication. Similar to typical AAAϩ proteins, the ATP-DnaA multimer on oriC is thought to adopt a spiral structure containing a central pore (Fig. 1) [29, 49] In this complex, the DnaA AAAϩ domain Arg finger (Arg-285) is required for the cooperative binding of ATP-DnaA molecules to moderate and low affinity DnaA-binding sites within DAR [24]. Rather than being uniform in overall structure, these results indicate that DnaA multimers formed on LL and RL-RE regions adopt structurally different inter-DnaA interaction modes, which may explain the functional difference between DnaA multimers These residues are evolutionarily conserved, and the corresponding mutants of the DnaA ortholog (tmaDnaA) from the ancient hyperthermophile Thermotoga maritima are inactive in DUE unwinding of its cognate oriC (tma-oriC). Our findings suggest a novel and common mechanism for ATP-DnaA-dependent activation of initial complexes
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