ivers and streams affected by mining activities often receive short-term sharp salinity increases due to water- soluble stockpiled materials being washed into receiving water bodies. We conducted a mesocosm study to ex- plore the response of structural (diatom and stream invertebrate communities) and functional descriptors (chlo- rophyll a concentration, fungal biomass and leaf decomposition) to repeated short salinity pulses (3 h of duration, with nominal electrical conductivities of 5, 10 and 15 mS cm−1), mimicking the exposure pattern occurring at salt-mine affected rivers. The experiment was conducted in 12 artificial flow-through stream systems over 16 days. The effect of the salt pulses on the ecosystem structure and functioning did not fully match most of our initial hypotheses, with the community response being weaker than predicted. The diatom community was, however, dominated by salt-tolerant species throughout the experiment, showing no consistent response to the treatment. The invertebrate response was associated with statistically significant changes in community structure (i.e. abundance of the different taxa) but no statistically significant changes in taxa richness. The salt pulses affected some functional descriptors of the ecosystem: fungal biomass exhibited a unimodal response to treatment magnitude, algal growth (i.e. chl a biomass) was hampered with increasing conductivity and leaf de- composition was significantly reduced in the high treatment.