This is not possible.
The definition of chirality ultimately relies on the superimposability of a structure on its mirror image. If they are non-superimposable, then the molecule is chiral. In terms of molecular symmetry, this is equivalent to saying:
If a molecule possesses an improper rotation axis $S_n$, then it is not chiral.
(An improper rotation is a combination of a normal rotation $C_n$ by $(360/n)^\circ$, followed by reflection in a plane perpendicular to that rotation axis.)
It turns out that the plane of symmetry and the inversion centre are the two most common forms of these (they are $S_1$ and $S_2$ respectively). Consequently, if a molecule has a plane of symmetry, it cannot be chiral. Likewise, if a molecule has an inversion centre, it cannot be chiral. There are also exotic molecules which possess neither a plane nor inversion centre, but possess a higher-order $S_n$ axis, and are therefore not chiral too.
However, the possession of a chiral centre has nothing to do with an $S_n$ axis. Consequently, there is no direct link between having a chiral centre and being chiral. Sure, there are trends that you can draw; for example, if there is only one chiral centre, then the molecule will not possess an $S_n$ axis, and thus it will be chiral. But the link is not quite as clear-cut as it is for the plane of symmetry, and consequently there are exceptions to the rule, and exceptions to the exceptions.
