Abstract
The ecotoxicological effects of engineered nanoparticles in aquatic environments are influenced not only by composition and size but also by particle morphology, yet shape dependent interactions with primary producers, remain poorly understood. In this study, we evaluated the cellular and molecular responses of freshwater algae ( Chlamydomonas reinhardtii ) following exposure to 100 nm silica-coated gold nanospheres (AuNP) and nanostars (AuNS) across multiple concentrations. Exposure to 10 mg/L AuNS for 72 h results in significantly stronger inhibition of algal growth and photosynthetic activity compared to the same concentration of AuNP. Morphometric profiling reveals that AuNS induced pronounced structural injury, including cell enlargement, debris production, and disruption of subcellular organization than AuNP. Confocal imaging suggested this heightened toxicity may stem from distinct internalization patterns, with AuNP primarily adhering to chloroplast surfaces, whereas AuNS penetrated more deeply into intracellular compartments. RNA sequencing identified 9 upregulated and 38 downregulated differentially expressed genes (DEGs) in the 10 mg/L AuNP treated cells, impairing photosynthesis and energy storage via the photosystem II subunit S1 (PSBS1)/ early light-inducible protein (ELI3) pathway. In contrast, the AuNS group exhibits 246 upregulated and 145 downregulated DEGs, affecting membrane integrity and nitrogen metabolism through the nitrate reductase (NIT1)/ aminomethyl transferase (AMT1)/ protein kinase domain-containing protein (A0A2K3CRU5) pathway. These results demonstrate that nanoparticle morphology can drive divergent toxicity mechanisms in algal cells. Our findings highlight the necessity of incorporating NPs morphology into environmental risk assessments and suggest that safer nanomaterial design should consider shape-dependent interactions with aquatic microorganisms.