Gut Microbiome is increasingly recognized as a pivotal player in toxicological responses, thus dysbiosis or microbial imbalance may worsen chemical-induced adverse outcomes such as inflammation, metabolic syndrome, and cancer. Early life exposure to environmental contaminants may produce long term toxicities in adulthood, and little is known to what extent early life exposure to environmental contaminants modulate the gut microbiome beyond adulthood. Therefore, this study tested the effects of perinatal exposure to 3 human health relevant environmental contaminants (BDE-47, TBBPA, and BPS), on the composition and functions of the gut microbiome of perinatally exposed adult male mice. CD-1 mouse dams were orally exposed to vehicle (corn-oil, 10ml/kg), BDE-47 (0.2mg/kg), TBBPA (0.2mg/kg), and BPS (0.2mg/kg) once daily from gestational day 8 to the end of lactation (postnatal day 21). Feces from male pups were collected at 12-weeks of age (n=14-23/group). Microbial DNA was isolated, subjected to 16rDNA sequencing, and analyzed using QIIME. Microbial biomarkers for each chemical exposure were predicted using LefSe. Microbial functions and key taxa that drive functional changes were predicted using PICRUSt and FishTaco, respectively. None of the 3 chemicals markedly altered the overall richness of the gut microbiome in adult male pups. However, principle coordinate analysis showed a distinct separation among different exposure groups, and especially between BPS and vehicle exposure groups. A total of 73 taxa were persistently altered by at least 1 chemical exposure, among which 12 taxa were commonly regulated by all 3 chemicals. The most representative microbial biomarkers for each exposure condition were Clostridiales for vehicle, S24-7 for BDE-47, Rikenellaceae for TBBPA, and Lactobacillus for BPS. Together, these observations suggest early life exposure to these human health relevant environmental contaminants produce persistent gut dysbiosis in adult male offspring, leading to functional shifts that may play important roles in regulating certain diseases of the host.