We investigate sum-rules applying to the Raman intensity in a strongly correlated system close to the Mott transition. Quite generally, it can be shown that provided the frequency integration is performed up to a cutoff smaller than the upper Hubbard band a sum-rule applies to the nonresonant Raman signal of a doped Mott insulator, resulting in an integrated intensity, which is proportional to the doping level. We provide a detailed derivation of this sum-rule for the $t\text{\ensuremath{-}}J$ model for which the frequency cutoff can be taken to infinity and an unrestricted sum-rule applies. A quantitative analysis of the sum-rule is also presented for the $d$-wave superconducting phase of the $t\text{\ensuremath{-}}J$ model, using slave-boson methods. The case of the Hubbard model is studied in the framework of dynamical mean-field theory, with special attention to the cut-off dependence of the restricted sum-rule and also to the intermediate coupling regime. The sum-rule investigated here is shown to be consistent with recent experimental data on cuprate superconductors, reporting measurements of Raman scattering intensities on an absolute scale.