An experimentally based investigation is presented of the dislocation structure and of glide effects occurring in single slip oriented nickel crystals cyclically deformed at 77 K until saturation of the stress amplitude. Special attention is paid to a comparison of slip and structure phenomena observed in fatigue tests at 77 K and those found after cycling at room temperature (RT) and elevated temperatures. At strain amplitudes within the plateau region of the cyclic stress-strain curve, where at higher temperatures in the crystal two structure types co-exist, at 77 K nearly the entire specimen volume is occupied by one structure "phase", a dislocation-"condensed" wall configuration. On different scale levels the main characteristics of this extended wall structure were found to be independent of the imposed amplitude, and they turned out to fit in the temperature dependence of the structure features of the ladder-like wall phase characterising the zones of intense slip (persistent slip bands) at RT and elevated temperatures. At 77 K the strain is localised in narrow slip bands (SBs) in the same way as at higher temperatures, although there is no indication of a "two-phase" structure. From the experimental findings it is concluded that WINTERs "two-phase" model remains valid, when averaging the plastic strain values over all SBs and over a sufficient number of cycles.