Introduction - Under climate change, temperatures and drought are expected to increase around the Mediterranean basin (IPCC, 2019) with an extended period of water stress in summer (Giannakopoulos et al., 2009). For Mediterranean rangelands, summer drought is a chronic stress factor that depends on soil types and water retention capacities. Water deficit was shown to be buffered by "adjusted" biomass production across a range of rangelands in contrasting soils (Barkaoui et al., 2017). However, we question to which extent increased drought can still be buffered to ensure the long term resilience of this rangeland. We hypothesise that successive increased summer droughts could alter the community towards a new state with a loss of ecosystem functions especially for communities on shallow soils with low water reserve. Material and methods - The study was carried out on dry calcareous rangelands of southem France, at the INRAe-La Fage experimental (43°55'N, 3°05'E, 790 m asl). The vegetation is dominated by perennial grasses with different species communities according to soil depth and texture. Four sites with sub-areas of sandy shallow soil (18±5 cm) and deep silty soil (85±17 cm) were identified. Increased summer drought treatment was applied in comparison with ambient summer drought treatment. Since June 2016 and for 5 years, we simulated a drier summer by setting a temporary rainout shelter for - 75 days from mid-June to end of August to create a warmer and drier micro-climate. Climatic parameters and soil moisture were monitored. Spring and autumn Aboveground Net Primary Production (ANPP) were measured in June and December each year, respectively. Vegetation cover (% bare soil) and the community structure(% monocots) were regularly assessed. Results and discussion - Rainout shelters intercepted between 105 to 25 mm (44 to 99 %) of rainfall water, increased average temperature of O. 7 to l.52°C and reduced relative humidity of 0.8 to 2.3 %, for shallow and deeper s