On Lie algebras of affine vector fields of real realizations of holomorphic linear connections

We study the properties of real realizations of holomorphic linear connections over associative commutative algebras $\mathbb A_m$ with unity. The following statements are proved.
If a holomorphic linear connection $\nabla$ on $M_n$ over $\mathbb A_m$ $(m\ge2)$ is torsion-free and $R\ne0$, then the dimension over $\mathbb R$ of the Lie algebra of all affine vector fields of the space $(M_{mn}^{\mathbb R},\nabla^{\mathbb R})$ is no greater than $(mn)^2-2mn+5$, where $m=\dim_{\mathbb R}\mathbb A$, $n=\dim_{\mathbb A}M_n$ and $\nabla^{\mathbb R}$ is the real realization of the connection $\nabla$.
Let $\nabla^{\mathbb R}=^1\nabla\times^2\nabla$ be the real realization of a holomorphic linear connection $\nabla$ over the algebra of double numbers. If the Weyl tensor $W=0$ and the components of the curvature tensor $^1R\ne0$, $^2R\ne0$, then the Lie algebra of infinitesimal affine transformations of the space $(M_{2n}^{\mathbb R},\nabla^{\mathbb R})$ is isomorphic to the direct sum of the Lie algebras of infinitesimal affine transformations of the spaces $(^aM_n,\,^a\nabla)$ $(a=1,2)$..