Reducing the intrinsic emittance of photocathodes is one of the most promising routes to improving the brightness of electron sources. However, when emittance growth occurs during beam transport (for example, due to space charge), it is possible that this emittance growth overwhelms the contribution of the photocathode, and, thus, in this case source emittance improvements are not beneficial. Using multiobjective genetic optimization, we investigate the role intrinsic emittance plays in determining the final emittance of several space-charge-dominated photoinjectors, including those for high-repetition-rate free electron lasers and ultrafast electron diffraction. We introduce a new metric to predict the scale of photocathode emittance improvements that remain beneficial and explain how additional tuning is required to take full advantage of new photocathode technologies. Additionally, we determine the scale of emittance growth due to point-to-point Coulomb interactions with a fast tree-based space-charge solver. Our results show that, in the realistic high-brightness photoinjector applications under study, the reduction of thermal emittance to values as low as50pm/μm(1 meV mean transverse energy) remains a viable option for the improvement of beam brightness.