We know that:
$\frac{Q'(z)}{Q(z)}=\sum\limits_{k=1}^{n}\frac{1}{(z-\alpha_k)}$
Thus
$\frac{P(z)}{Q(z)}=\sum\limits_{k=1}^{n}\frac{P(z)}{Q'(z)(z-\alpha_k)}$
This is about as far as I have traveled any ideas?
I get the feeling that I should use :
But I am not sure of it's relevancy.
On
Let $$R(z):=Q(z)\cdot\sum_{k=1}^{n}\frac{P(\alpha_k)}{Q'(\alpha_k)(z-\alpha_k)}=\sum_{k=1}^{n}\frac{P(\alpha_k)}{Q'(\alpha_k)}\cdot\frac{Q(z)}{z-\alpha_k}.$$ Then $R$ is a polynomial of degree $\leq n-1$ such that for $j=1,\dots,n$, $$\lim_{z\to \alpha_j}R(z)=\sum_{k\not=j} \frac{P(\alpha_k)Q(\alpha_j)}{Q'(\alpha_k)(\alpha_j-\alpha_k)}+ \frac{P(\alpha_j)}{Q'(\alpha_j)}\lim_{z\to \alpha_j}\frac{Q(z)}{z-\alpha_j} = \frac{P(\alpha_j)Q'(\alpha_j)}{Q'(\alpha_j)}=P(\alpha_j)$$ (recall that $Q(\alpha_k)=0$ and $Q'(\alpha_k)\not=0$ for $k=1,\dots,n$).
Hence the polynomials $P$ and $R$ coincide in $n$ points. What may we conclude?
We know that, for some $K\in\mathbb{C}\setminus\{0\}$, $Q(z)=K(z-\alpha_1)(z-\alpha_2)\cdots(z-\alpha_n)$. So, by partial fraction decomposition, $\frac{P(z)}{Q(z)}$ can be written as$$\sum_{k=1}^n\frac{\beta_k}{z-\alpha_k}.$$Besides,$$\beta_k=\lim_{z\to\alpha_k}(z-\alpha_k)\sum_{k=1}^n\frac{\beta_k}{z-\alpha_k}=\lim_{z\to\alpha_k}\frac{P(z)}{\frac{Q(z)}{z-\alpha_k}}=\frac{P(\alpha_k)}{Q'(\alpha_k)}.$$