Recall the definition of a generic point: a point $\eta$ of a scheme $X$ is generic if $\overline{\eta}=X$.
The scenario here is that $Z$ is an irreducible closed subscheme of a scheme $X$, and $U,V$ are affine open subschemes of $Z$.
Recall that from topology, a subset $A\subset B$ is dense if $\overline{A}=B$ or equivalently $A$ intersects every nonempty open subset of $B$.
Let $\eta_U$ be the unique generic point of $U\cap Z$. The closure of $\eta_U$ in $U$ is $U\cap Z$. The the closure of $\eta_U$ in $X$ must contain $U\cap Z$, which means that it must be all of $Z$. This is true for the following reason: suppose it wasn't all of $Z$ - then $Z\setminus (U\cap Z)$ and $\overline{\eta_U}$ would be a decomposition of $Z$ into two proper nontrivial closed subsets, which would give that $Z$ is reducible.
Since $\overline{\eta_U}=Z$, it is a dense subset of $Z$, and thus must be contained in every nonempty open subset of $Z$. In particular, $\eta_U\in V\cap Z$. The closure of $\eta_U$ in $V\cap Z$ is $V\cap Z$, so $\eta_U$ is also a generic point for $V\cap Z$, and thus must equal the generic point $\eta_V$ of $V\cap Z$. This is true because we've shown (or Jim has suggested) that for any affine scheme, there is a unique generic point.
