Helicase associated 2 domain is essential for helicase activity of RNA helicase A

RNA helicase A (RHA), a DExD/H box protein, plays critical roles in a wide variety of cellular or viral functions. RHA contains a conserved core helicase domain that is flanked by five other domains. Two double-stranded RNA binding domains (dsRBD1 and dsRBD2) are at the N-terminus, whereas HA2 (helicase associated 2), OB-fold (oligonucleotide- or oligosaccharide-binding fold), and RGG (repeats of arginine and glycine–glycine residues) domains are at the C-terminus. The role of these domains in the helicase activity of RHA is still elusive due to the difficulty of obtaining enzymatically active mutant RHA. Here, we purified a series of mutant RHAs containing deletions in either N-terminus or C-terminus. Analysis of these mutant RHAs reveals that the dsRBDs are not required for RNA unwinding, but can enhance the helicase activity by promoting the binding of RHA to substrate RNA. In contrast, deletion of C-terminal domains including RGG, OB-fold, and HA2 does not significantly affect the binding of RHA to substrate RNA. However, HA2 is essential for the RNA unwinding by RHA whereas the RGG and OB-fold are dispensable. The results indicate that the core helicase domain alone is not enough for RHA to execute the unwinding activity.     

One-pot fluorescent labeling of saccharides with fluorescein-5-thiosemicarbazide for imaging polysaccharides transported in living cells

A simple and efficient procedure for the fluorescent labeling of saccharides is a prerequisite step for imaging the transport of polysaccharides in living cells. We report a one-pot strategy for the fluorescent labeling of saccharides with fluorescein-5-thiosemicarbazide (FTSC), which introduces the thiosemicarbazide group of FTSC to the aldehyde group at the reducing end of saccharides to form stable amino derivatives via reductive amination. The Glc-FTSC derivative was characterized by HPLC–MS, HRESIMS and NMR spectroscopy. Saccharides were quantitatively labeled with FTSC at 75 °C for 1 h under optimum reaction conditions. Fluorescence studies illustrated that the conjugation of FTSC to saccharides did not change its florescence properties (λ_ex = 495 nm, λ_em = 517 nm), presenting desirable compatibility with commonly used fluorescence equipment. Polysaccharide AAG-FTSC derivatives exhibited rather low levels of cytotoxicity against rat thymus cells, and the fluorescent labeling procedure had slight impact on their anti-tumor activity. Results indicate that the assay neither introduces discernible cytotoxicity against living cells nor obviously alters the functional activities of polysaccharides, and provides a convenient, highly efficient fluorescent labeling approach for imaging the transport of polysaccharides in living cells.