The importance of water for life is undeniable. However, modern industrial and urban practices have led to the pollution of water reservoirs. Efficient wastewater purification is crucial for sustainability, and several materials with specific characteristics have been investigated to improve water quality. The integration of polyoxometalates (POMs) into metal-organic frameworks (MOFs) holds significant potential for water treatment applications due to their complementary properties. POMs are renowned for their high catalytic activity, redox versatility, and resistance to harsh environments, while MOFs offer high porosity, tunable chemical environments, and enhanced stability. When immobilized within MOF structures, POMs can exhibit improved processability and recyclability, overcoming limitations such as leaching and aggregation. The resulting composites maintain the catalytic efficiency of POMs and leverage the structural and adsorptive characteristics of MOFs to target contaminants in water. These hybrid systems are up-and-coming with improved characteristics where the synergy between the POM's catalytic sites and the MOF's porous network can facilitate efficient degradation of organic pollutants, heavy metal sequestration, and enhanced adsorption of micropollutants, paving the way for sustainable water purification technologies. This review encapsulates the latest advancements in POM-MOF composites, discussing the predominant synthesis strategies and their applications, particularly in wastewater treatment. Furthermore, POM-MOF composite nanoplatforms for wastewater treatment are explored based on their high stability and large specific surface area, making them an ideal choice for waste-water treatment.