Symplectic maps of complex domains into complex space forms

Let $M\subset{\complex}^n$ be a complex domain of ${\complex}^n$ endowed with a rotation invariant \K form $\omega_{\Phi}= \frac{i}{2} \partial\bar\partial\Phi$. In this paper we describe sufficient conditions on the \K potential $\Phi$ for $(M, \omega_{\Phi})$ to admit a symplectic embedding (explicitely described in terms of $\Phi$) into a complex space form of the same dimension of $M$. In particular we also provide conditions on $\Phi$ for $(M, \omega_{\Phi})$ to admit global symplectic coordinates. As an application of our results we prove that each of the Ricci flat (but not flat) \K forms on ${\complex}^2$ constructed by LeBrun (Taub-NUT metric) admits explicitely computable global symplectic coordinates.