Abstract
The active form of many helicases is oligomeric, possibly because oligomerization provides multiple DNA binding sites needed for unwinding of DNA. In order to understand the mechanism of the bacteriophage T4 Dda helicase, the potential requirement for oligomerization was investigated. Chemical cross-linking and high pressure gel filtration chromatography provided little evidence for the formation of an oligomeric species. The specific activity for ssDNA stimulated ATPase activity was independent of Dda concentration. Dda was mutated to produce an ATPase-deficient protein (K38A Dda) by altering a residue within a conserved, nucleotide binding loop. The helicase activity of K38A Dda was inactivated, although DNA binding properties were similar to Dda. In the presence of limiting DNA substrate, the rate of unwinding by Dda was not changed; however, the amplitude of product formation was reduced in the presence of increasing concentrations of K38A Dda. The reduction was between that expected for a monomeric or dimeric helicase based on simple competition for substrate binding. When unwinding of DNA was measured in the presence of excess DNA substrate, addition of K38A Dda caused no reduction in the observed rate for strand separation. Taken together, these results indicate that oligomerization of Dda is not required for DNA unwinding.
Highlights
The active form of many helicases is oligomeric, possibly because oligomerization provides multiple DNA binding sites needed for unwinding of DNA
When unwinding of DNA was measured in the presence of excess DNA substrate, addition of K38A Dda caused no reduction in the observed rate for strand separation
Biochemical assays in which the ATPase activity of Dda was measured at varying enzyme concentration did not provide any evidence for oligomerization (Fig. 3)
Summary
The active form of many helicases is oligomeric, possibly because oligomerization provides multiple DNA binding sites needed for unwinding of DNA. When dsDNA1 is replicated, repaired, or recombined, the necessary ssDNA intermediates are provided by the activity of helicases [1,2,3,4,5]. These enzymes appear to be ubiquitous, having been identified in viral, bacterial, and eukaryotic systems. Usually ATP, to obtain the energy needed to unwind dsDNA They translocate on DNA often in a very processive manner, unwinding thousands of base pairs in a single binding event. The oligomeric nature of Dda was investigated in order to determine whether its relatively low processivity might be related to the oligomeric structure, and to lay the foundation for future mechanistic studies
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