The quest for topological states in strongly correlated materials is challenging but essential from fundamental research and application perspectives. The magnetic Weyl semimetal (WSM) state in the chiral antiferromagnet Mn3Sn emerges with strong electronic correlations, offering an intriguing arena for exploring the interplay between Weyl fermions and correlation physics. One prominent characteristic of the WSM state is the chiral anomaly, yet the potential effects of electronic correlations on the chiral anomaly remain unexplored. Here, we report a comprehensive study of the in-plane magnetotransport properties of single-crystal Mn3+xSn1−x with three different Mn doping levels (x = 0.053, 0.070, and 0.090). The excess Mn leads to glassy ferromagnetic behavior and the Kondo effect, aside from shifting the chemical potential relative to the Weyl nodes. Thus, systematic tuning of the Mn doping level enables us to study the interplay between the spin-fluctuation scatterings, the correlation effect, and the chiral anomaly. We identify negative longitudinal magnetoresistance and planar Hall effect specific to the chiral anomaly for all three doping levels, indicating that the chiral anomaly persists in the presence of strong correlations.