This thesis explores the resilience and performance of geosynthetic-reinforced soil (GRS) structures under extreme weather conditions, such as heavy rainfall and floods, which are intensifying due to climate change. Renowned for their versatility, cost-effectiveness, and rapid construction, GRS structures are pivotal in civil infrastructure. However, failures often occur due to using marginal backfill soils with high fines content and suboptimal design practices. This study aims to fill a gap by assessing how severe weather affects GRS walls. A series of model tests and numerical simulations were conducted to examine the impact of rainfall and flooding on GRS wall stability. The experiments evaluated the effectiveness of different reinforcement stiffness, vertical spacing, and the presence of sand cushions in enhancing wall stability. A reduced scaled model (N = 5) was used to represent 3-meter prototype GRS walls exposed to flood conditions up to two-thirds of the wall height or rainfall intensities of 75mm/hr. Key metrics such as phreatic surface levels, wall deformations, and reinforcement tensile strains were monitored and analyzed. The result indicates that in rainfall simulations, reducing the spacing between reinforcements or incorporating sand cushions controlled wall deformations effectively and modified failure modes. Notably, the sand layer improved pullout resistance, strength, and drainage properties. During flood conditions, both increasing reinforcement stiffness and reducing vertical spacing were effective, with the latter proving more significant in mitigating wall deformations. Based on soil mechanics, regulations recommend using backfill with fines content more than 15%. However, numerical simulations showed that the relationship between fines content and safety factor is nonlinear, and the most critical safety factor occurs at a fines content of 6%. Demonstrating that the failure mechanism differs from the traditional mechanical mode under hydraulic conditions. Based on these findings, the thesis discusses design strategies for using GRS walls as effective waterfront protection structures, highlighting adaptations to counteract the challenges posed by climate change.