Equivariant quantization of Poisson homogeneous spaces and Kostant's problem

Let $\mathfrak g$ be a finite dimensional split semisimple Lie algebra and $\lambda$ a weight of $\mathfrak g$. Let $F$ be the algebra of quantized regular functions on the connected simply connected group $G$ corresponding to $\mathfrak g$. In the present paper we introduce a certain subspace $F'$ of $F$ (which is not necessary a subalgebra of $F$) and endow it with an associative $\star$-product using the so-called reduced fusion element. We prove that the algebra $(F',\star)$ is isomorphic to $(L(\lambda))_{fin}$, where $L(\lambda)$ is the irreducible highest weight $\check{U}_q\mathfrak g$-module and "$fin$" stands for the subalgebra of the locally finite elements with respect to the adjoint action of $\check{U}_q\mathfrak g$. The introduced $\star$-product has some limiting properties what enables us to prove Kostant's problem for $\check{U}_q\mathfrak g$ in certain cases. We remind the reader that this means that $(L(\lambda))_{fin}$ coincides with the image of $\check{U}_q\g$ in $L(\lambda)$. We also note that if $\lambda$ is such that $<\lambda,\alpha_i^\vee>=0$ for some simple roots $\alpha_i$ and generic otherwise, then $(F,\star)$ is a $\check{U}_q\mathfrak g$-invariant quantization of the Poisson homogeneous space $G/K$, where $K$ is the stabilizer of $\lambda$.