The long-range electrostatic interaction between a pair of similarly charged colloidal spheres and a charged planar wall at low surface potentials is theoretically investigated. The linear Poisson-Boltzmann equation (PBE) and the point charge approximation of the charged sphere are used, The electrical potential distribution in the electrolyte solution is found from the PBE at the constant surface potentials using the image charge method. The electrostatic forces acting on the spheres are then calculated. The results show that the repulsive interaction between a pair of similarly charged colloidal spheres clearly decreases when a charged wall appears nearby, but it is impossible for an attractive force to emerge at the scaled surface potentials less than 1, There is, however, an attractive force between the charged wall and the similarly charged colloidal spheres, when the surface potential zeta(p) on the wall is sufficiently higher than the surface potential zeta(s) on the spheres to make zeta(p) > zeta(s)exp(kappa h) (h is the distance from the wall to the sphere center). In this case, there are negative surface charges on the spheres at positive surface potential zeta(s), It is these negative charges that produce the above attraction.