Zirconia loaded with tungsten oxide (abbreviated as WZ) has been reported to be an efficient solid catalyst at relatively low temperatures in the skeletal isomerization of alkane or benzoylation of toluene, which are usually catalyzed by strong acids. In order to increase the surface area of tungstated zirconia, which is usually around 50 m2/g, mesoporous SBA-15 with a uniform hexagonal array of channel-shaped mesopores and very high surface area (typically around 800 m2/g) was used as the support for preparing supported WZ catalysts. In the present study, the supported WZ catalysts were prepared by depositing precipitation methods, and the catalytic activities of the resultant materials were compared in n-pentane isomerization reaction. Factors of catalyst preparation such as the method of supporting WZ on SBA-15, the weight ratios of tungsten and zirconia to SBA-15, the calcination temperature of the composite materials, and the addition of Pt were examined. The catalyst prepared through supercritical ethanol was found to retain well ordered porous structure based on small angle X-ray diffraction measurements and high surface area by nitrogen sorption experiments. On the contrary, SBA-15 supported tungstated zirconia prepared by direct evaporation was found to have the mixed oxide particles block the pores of SBA-15. The impregnation of 1% Pt on the materials before used as the catalyst in n-pentane isomerization and the inlet of hydrogen flow during reaction were found to be essential. The SBA-15 supported WZ catalyst with the weight ratio of WO3 : ZrO2 : SBA-15 in 1: 2: 2 prepared by supercritical ethanol treatment showed the highest isomerization activity than the others. The main product of isomerization reaction was iso-pentane. The selectivity of the isomerization reaction and the deactivation of catalysts were also found to vary with the feed of hydrogen gas.