Help in recovering the Rutherford formula for $epto ep$ scattering in the nonrelativistic limit

If the proton were a point charge like the muon, then $epto ep$ scattering, the differential scattering crossection is $$frac{dsigma}{dOmega}Bigg|_{rm lab}=Bigg(frac{alpha^2}{4E^2sin^4(theta/2)}Bigg)Bigg{1+frac{2E}{m_p}sin^2thetaBigg}^{-1}Bigg[cos^2(theta/2)-frac{q^2}{2m^2_p}sin^2(theta/2)Bigg]$$ where $theta$ is angle scattering, $E,E’$ are the initial and final energies of the scattered electron, $q$ is the momentum transfer in the scattering and $m_p$ is the mass of the proton. In the limit of $m_pto infty$, or more accurately, $E,q^2ll m_p^2,$ the term inside the second bracket becomes unity and second term inside the third bracket vanishes. In this limit, we get $$frac{dsigma}{dOmega}Bigg|_{rm lab}rightarrowBigg(frac{alpha^2}{4E^2sin^4(theta/2)}Bigg)cos^2(theta/2)$$ where the quantity inside the first bracket is the Rutherford scattering formula.

Why does the factor $cos^2(theta/2)$ survive in this limit? Why we do not recover the exact Rutherford formula in this limit nonrelativistic limit?