Oligoarginine-conjugated lipids ((Arg)n-PEG-lipid) (n=4, 6, 8, and 10: number of arginine residues) are novel gene delivery vectors. We prepared two oligoarginine-modified liposomes using (Arg)n-lipid without and with poly(ethylene glycol) (PEG) spacer ((Arg)n-L and (Arg)n-PEG-L), and investigated the effect of PEG spacer and oligoarginine length of liposomes on cellular uptake, gene transfection, and its mechanism in HeLa cells, using complexes with plasmid DNA (DNA) or oligodeoxynucleotide. Transfection efficiency increased as the number of arginine residues increased and Arg10-PEG-L/DNA complexes (lipoplexes) showed the highest gene transfection efficiency among (Arg)n- and (Arg)n-PEG-lipoplexes. Arg4- and Arg4-PEG-lipoplexes were taken up greatly into cells, but showed lower transfection efficiency than Arg10- and Arg10-PEG-lipoplexes, respectively. The different gene expression by Arg4-L to Arg10-L with or without PEG spacer may be explained by the different intracellular uptake mechanism. The main cellular uptake mechanism of Arg10-L and Arg10-PEG-L was the macropinocytosis pathway, whereas that of Arg4-L and Arg4-PEG-L was not. PEG spacer was more effective for intracellular trafficking than Arg length and surface charge of lipoplex which depends on Arg length at the almost same size of lipoplexes. The findings suggested that Arg10-PEG-L was a superior vector since Arg10 induced the macropinocytosis uptake pathway.