It is well-known that uniformly charged polyelectrolytes such as DNA migrate with the same mobility regardless of chain length. However, they may be separated by free solution electrophoresis if an uncharged particle is attached to the one end of the polyelectrolyte. On the basis of Monte Carlo simulations, the mobility μ of a polyelectrolyte of length Nc attached with an neutral polymer of length Nu is investigated. According to the Rouse (free-draining) picture, it is anticipated that the mobility becomes size-dependent and follows μ(Nc) ∝ Nc/(Nc+Nu). The additional resistance provided by the neutral section breaks the balance between the electric driving force (Nc) and hydrodynamic drag (Nc+ Nu). Our simulation results indicate that although the end label offers the broken symmetry but the aforementioned relation is not valid due to the interaction friction. With both ends are labeled with neutral polymers of Nu* and Nu-Nu*, it is found that the mobility increases as Nu*/(Nu-Nu*)→1. In weak electric field, the conformation may change from random coil to charge-neutral segregation regime as the ratio Nc/(Nc+ Nu) is decreased. Because the conformations are different with/without electric field, the Nernst-Einstein equation is not valid for end-labeled polyelectrolytes.