Due to its high optical transparency and low resistivity, ITO has been widely used in LCDs, touch panels and solar cells in the recent years. Because of its huge contribution to human’s technology, the conduction mechanisms and electrical properties of ITO deserve more in-depth studies. We have measured a series of ITO nanowires with different levels of disorder. The electron dephasing lengths, which decrease with increasing temperature, are extracted from weak-localization magnetoresistance measurements. When the dephasing length is close to the nanowire diameter, the weak-localization effect will cross over from being one-dimensional to being three-dimensional. In one low- resistivity (200 cm    at 300 K) nanowire, a long dephasing length was observed, which varied from about 500 nm at 0.25 K to 150 nm at 40K. Therefore, the nanowire revealed one-dimensional behavior over the whole measurement temperature range. In one high-resistivity (1000  cm at 300 K) sample, we got a dephasing length of 200 nm at 0.26 K. When the temperature increased,  L became smaller than the diameter of the sample, and hence a crossover from one-dimensional to iii three-dimensional weak-localization effect was observed. In particular, we found disorder-induced spin-orbit interaction in the high-resistivity sample. In this case, weak anti-localization occurred in the low temperature region. This result demonstrates that the dephasing length and the strength of spin-orbit interaction can be tuned by varying the level of disorder in ITO nanowires.