69Ga nuclear magnetic resonance (NMR) line shift ( 69 K) and nuclear spin–lattice relaxation rate ( 69 T 1 −1) are measured for Pu 0.95Ga 0.05 alloy, stabilized in δ-phase, in the temperature range 10 and 650 K at magnetic field of 9.4 T. The shift and 69 T 1 −1 are determined correspondingly by the static and fluctuating-in-time parts of the local magnetic fields arisen at Ga due to transferred hyperfine coupling with the nearest f electron environment of more magnetic Pu. At T > 200 K, the temperature dependent part of the shift 69 K( T) scales macroscopic magnetic susceptibility χ( T), following the Curie–Weiss law, and the product ( 69 T 1 T) increases with temperature proportionally ( T + 255) 1.5(1). Both of the NMR observations are typical of the incoherent spin fluctuation regime of f electrons in nonmagnetic 3D Kondo lattice. An estimate of the effective magnetic moment μ eff,5f( g e = 2) = 0.15(5) μ B per Pu atom points out a strong suppression of the spin magnetism in the alloy.