Malaria, caused by thePlasmodium falciparum, remains a significant global health challenge, with Plasmodium falciparum accounting for approximately 50% of cases and posing a considerable threat. Despite advances in control measures, malaria continues to cause an estimated one million deaths annually. The complex lifecycle ofP. falciparum, involving both vertebrate hosts and Anopheles mosquitoes, complicates eradication efforts. The parasite’s resistance to existing antimalarial drugs, along with medication toxicity, necessitates innovative therapeutic approaches.Recent research has revealed that harmine, an alkaloid produced by an endophytic gut bacterium of Anopheles mosquitoes, can impede the transmission of the malarial parasite to humans by inhibiting a crucial life stage. This study investigates harmala alkaloids, sourced from plants and bacteria such asPeganum harmala, as potential alternatives to conventional antimalarial drugs. Notably, harmine and harmaline have shown promising antimalarial activity by inhibiting the essential enzyme protein kinase 4 (PK4), which is vital for the parasite’s survival. These compounds exhibit lower toxicity, effectively inhibiting both the blood stage growth and transmission of the parasite. Using in silico methodologies, including ADME analysis, molecular docking, MD simulation, and toxicity analysis, this study identifies harmala alkaloids as potential inhibitors against crucialP. falciparumproteins. Targeting proteins essential for the parasite’s survival, similar to established drugs like pfCRT protein, lays the foundation for developing effective antimalarial treatments. The comprehensive screening of harmala alkaloid molecules opens avenues for the pharmaceutical industry to tackle challenges related to drug resistance and toxicity, offering a promising route for the biorational management of malaria.