Abstract
Proteins from Sulfolobus solfataricus (S. solfataricus), an extremophile, are active even at high temperatures. The single-stranded DNA (ssDNA) binding protein of S. solfataricus (SsoSSB) is overexpressed to protect ssDNA during DNA metabolism. Although SsoSSB has the potential to be applied in various areas, its structural and ssDNA binding properties at high temperatures have not been studied. We present the solution structure, backbone dynamics, and ssDNA binding properties of SsoSSB at 50 °C. The overall structure is consistent with the structures previously studied at room temperature. However, the loop between the first two β sheets, which is flexible and is expected to undergo conformational change upon ssDNA binding, shows a difference from the ssDNA bound structure. The ssDNA binding ability was maintained at high temperature, but different interactions were observed depending on the temperature. Backbone dynamics at high temperature showed that the rigidity of the structured region was well maintained. The investigation of an N-terminal deletion mutant revealed that it is important for maintaining thermostability, structure, and ssDNA binding ability. The structural and dynamic properties of SsoSSB observed at high temperature can provide information on the behavior of proteins in thermophiles at the molecular level and guide the development of new experimental techniques.
Highlights
Sulfolobus is one of the well-known hyperthermophilic archaebacterial genera [1].Unlike mesophilic eukaryotes and bacteria, which are sensitive to external conditions, Sulfolobus can survive at extremely low pH or high temperature [1–5]
SSBshave havehighly highly conserved sequences ranging mesophiles to hyperthermoSSBs conserved sequences ranging fromfrom mesophiles to hyperthermophiles philes (Figure has a unique containingan an (Figure 1)
We investigated the solution structure, DNA binding properties, and dynamic properties of the thermophilic SsoSSB at high temperature (50 ◦ C)
Summary
Unlike mesophilic eukaryotes and bacteria, which are sensitive to external conditions, Sulfolobus can survive at extremely low pH or high temperature [1–5]. Sulfolobus solfataricus (S. solfataricus) is adapted to high temperature via lipid composition changes [6], protection of its DNA with DNA binding proteins [7], and expression of a unique DNA topoisomerase [8]. Because they have the ability to survive in such harsh conditions, proteins from. S. solfataricus are widely used in biological experiments and industrial applications that require low pH or high-temperature conditions [5]. Single-stranded DNA (ssDNA) binding proteins (SSBs) of S. solfataricus are used in biotechnological applications under harsh conditions.
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