$S_1(n,0)=S_1(0,n)= \delta_n \; \;$ and, for $n > 0$, 

$$S_1(n,k)= \lim_{y \to 0} \;  \frac{y^{-k}}{k!} \; \sum_{j=1}^k (-1)^j \binom{k}{j} \; \frac{(-j \; y)!}{(-j \; y-n)!} \;$$

$$ = \lim_{y \to 0} \;  \frac{y^{-k}}{k!} \; \sum_{j=1}^k (-1)^{n-j} \binom{k}{j} \; \frac{(j \; y - 1 + n)!}{(j \; y-1)!} \; $$

$$= \sum_{j=k}^n \; S_1(n,j)\; (-y)^{j-k}\;S_2(j,k) \; |_{y=0} \; . $$

For a derivation, see [A class of differential operators and the Stirling numbers][1]. Note that with $y$ small enough taking the nearest integer generates $S_1$.


  [1]: http://tcjpn.wordpress.com/2015/08/23/a-class-of-differential-operators-and-the-stirling-numbers/#more-2614