While nitrate (NO3-) serves as a vital nutrient for soil organisms, the lack of knowledge on its sources and cycling in Antarctic soils does not allow to predict the possible effects of climate and environmental changes on the functioning of terrestrial ecosystems. Thus, the NO3- and its stable isotopes of Delta O-17(NO3), delta N-15(NO3,) and delta O-18(NO3) were analyzed in Antarctic soils, collected in coastal ice-free areas of East Antarctica and the tip of the northern Antarctic Peninsula. The soil NO3- concentrations and isotopic values of Delta O-17(NO3), delta N-15(NO3,) and delta O-18(NO3) were comparable across the latitudinal gradient except for soils collected beneath moss cushions in the Fildes Peninsula. The proportional calculation of Delta O-17(NO3) indicated that 93-97% of soil NO3- derived from nitrification process, whereas atmospheric deposition probably contributed to the NO3- budget for a fraction <10 %. The linear relationship between delta O-18(NO3) and delta N-15(NO3) suggested the occurrence in Antarctic soils of denitrification process and active cycling between NO3- and nitrite (NO2-). The NO3- assimilation in soil likely occurred, but at minimal rates. These findings provide new insights in the biogeochemical cycle of nitrogen (N) in Antarctic terrestrial ecosystems and seem to indicate that despite climatic and environmental changes along the wide latitudinal gradient, the sources and cycling of NO3- maintain a rather consistent pattern along coastal ice-free areas. The noteworthy increase of NO3- concentrations and delta N-15(NO3), delta O-18(NO3), and Delta O-17(NO3) values in soils collected under moss in the Fildes Peninsula could also suggest that the warming and the increased availability of liquid water will likely favor the developments of soil biotic communities and changes in the biogeochemical cycle of N in Antarctic terrestrial ecosystems.