This is by no means a complete answer, but just to get the ball rolling while I have a moment spare, let me write some things down. However, I strongly encourage you to add some background to your question, explaining why you are asking it, where you came across the problem, and so on. This seems like a basic courtesy when asking questions, although perhaps I am overly touchy on this issue.
Anyway.
Consider the case of $G$ discrete. For each $x\in G$ let $\lambda_x \in VN(G) \subset B(\ell^2(G))$ be the usual operator of left translation. Define $S:\ell^1(G) \to B(B(\ell^2(G))$ by
$$ S(f)(T) = \sum_{x\in G} f(x) \lambda_x^{-1} T \lambda_x \qquad (f\in\ell^1(G), T\in B(\ell^2(G)). $$
Then you can check that $S$ defines a right action of $G$ on $B(\ell^2(G))$. Moreover, if $u\in \ell^\infty(G)$ and $M_u\in B(\ell^2(G))$ is the corresponding diagonal multiplication operator, a direct calculation shows that
$$ S(\delta_x)(M_u) = M_{x\cdot u}$$
where $(x\cdot u)(t) = u(xt)$. So $M(\ell^\infty(G))$ becomes a right sub-module for this action, and as a right module it is isomorphic to $\ell^\infty(G)$ with the right action you defined at the start.
A similar argument, using the right von Neumann algebra rather than the left one, will get you a left action of $G$ on $B(\ell^2(G))$ for which $M(\ell^\infty(G))$ is again a submodule, isomorphic to $\ell^\infty(G)$ with the left action that you defined at the start.
(IIRC, the first place I saw this representation was in an article of Bunce, where it is used in the proof that for $G$ discrete, amenability of $C_r^*(G)$ implies $G$ is amenable. I suspect it was already part of the experts' folklore by then, so I don't know who first noticed this. Similar ideas are surely there in the purely algebraic setting, this is one of the canonical ways to make End(V) into a G-module when V is a G-module.)
I think the argument should go through without difficult for unimodular locally compact groups, so I leave it to you. In the non-unimodular case, I am not sure without further checking.